QUESTION:
If Hydrogen is the simplest molecule, was it also the first?
ANSWER:
I presume you mean simplest atom.
It is believed that the very early universe was nearly pure hydrogen
with a small amount of helium and a smaller yet amount of lithium.
QUESTION:
Free neutrons are unstable. But free nutrons are used in
fission reactions, neutron scattering and other processes. How is that
possible? Don't the neutrons get converted into protons on the courese
of motion?
ANSWER:
The average lifetime of a neutron is about 15
minutes, so their use in the applications you mention is not appreciably
affected.
QUESTION:
What is meant by "spin = 1/2" for elctrons?
DOes it have anything to do with the spinning of electrons?What is the
physical significance of the quantity "spin quantum number"?
ANSWER:
Elementary particles, like classical particles, may have
angular momentum. A particle may have orbital angular momentum (like an
electron orbiting around the nucleus in an atom or like the earth
orbiting the sun) or it may have intrinsic angular momentum (like the
earth spinning on its own axis or like the spin angular momentum of the
elementary particle). When one goes to the microscopic level of
elementary particles, angular momentum is quantized, that is only
discrete amounts of angular momentum are allowed; for example, if the
angular momentum quantum number of a particle is L, its angular momentum
is [h/(2π)]√{L(L+1)} where h is Planck's constant. For a spin �
particle, the intrinsic angular momentum quantum number is � and so the
particles intrinsic angular momentum is h√3/(4π). Although it is
sometimes described as spinning of the particle about its own axis, this
is a classical picture which is useful only as a rough means of
understanding what spin is. For example, it is impossible to do anything
to change the spin of the particle.
QUESTION:
All the diagrams of
electromagnetic waves that I have seen in textbooks show the electric
and magnetic waves being 180 degrees out of phase. I always thought that
the decay of one field caused a buildup of the other and that this would
put them 90 degrees out of phase. Are the pictures wrong?
ANSWER:
I do not understand what you mean by phase. In the figure to the right
the electric and magnetic fields are in phase; this is the diagram you
normally see. The fields are in phase in a vacuum or a nonconducting
medium. In a conducting medium they are not in phase, but I do not think
that is what you are interested in. This phase relationship is what is
predicted by solving Maxwell's equations. What is shown here is what is
called a sinesoidal plane-polarized plane wave; the wave fronts are
infinite planes, the electric fields are everywhere along one dimension
and the magnetic fields are everywhere along one dimension perpendicular
to the direction of the electric fields.
QUESTION:
if an object
falls towards the earth is because it is atracted by the earht's gravity
OR it is because it's following the path of the space curved by the
earth's mass and density? Second, is it true that every object in space
is affected by the gravity of every object, but in very very very small
quantities?
ANSWER:
Our best understanding, based on general
relativity, is that it is the latter�space-time is curved. But the
consequences of general relativity can be understood as saying that
objects with gravitational mass attract each other. Certainly, any
object with mass will attract any other.
QUESTION:
I am
wondering if my idea is valid, since I have never seen it used before.
It seems to me that a rocket launched vertically wastes a great deal of
fuel just overcoming inertia AND gravity; and it seems to me that a
rocket launched on a horizontal track, like a roller-coaster, which
curves upward to the vertical would overcome inertia immediately, and
upon leaving the vertical end of the track , would already have attained
great speed. Can you tell me the pros and cons of this launch method?
ANSWER:
In the absense of friction it makes no difference how
you get from point A to point B because the forces are conservative. You
make it sound like you just overcome inertia and then can move on to
overcoming gravity. In fact, the rocket has the same inertia regardless
of its motion, it is not something you can just get rid of. Using a
horizontal track would increase the friction compared to air friction,
so it would be less efficient overall. Since the rocket will go very
fast, air friction becomes important and so going vertically originally
gets you out of the atmosphere as quickly as possible. You can get a
little boost by using the rotation of the earth; that is why launch
sites are as far south as practicable, for example France launches from
French Guiana in South America.
QUESTION:
I have been reading
about the new LHC (Large Hadron Collider) that will begin running in
Europe soon. I noticed that the LHC will use proton-proton collisions.
My question is, why did they decide to use proton-proton collisions
instead of proton-antiproton collisions? It seems to me that
proton-antiproton collisions would be more advantageous since protons
and anitprotons attract and are therefore easier to make collide and
protons and antiprotons also produce a disintegration energy when they
collide that would add to the attainable energy of the collider.
ANSWER:
The main reason is that it is difficult to get an intense
antiproton beam; the antiprotons first have to be made and then bunched
together and accelerated. When doing experiments that look for rare
events, intensity of the beam is paramount to give one a chance to see
the event. Also, your ideas regarding an advantage from the attraction
or the "disintegration" is flawed because the kinetic energies (TeV) are
so high that the weak coulomb attraction is a negligible component and
the mass energy of a proton-antiproton pair (around 2 GeV) is also
neglibible.
QUESTION:
My Physics teacher was talking about
electrons moving further away from the core when the atom is heated, and
then unleasing energy as they move back, when the atom gets colder
again... My question is; would it be theoretically possible to utilise
that energy to knock a proton out of the core, or make it change
polarity and remove itself from the core?
ANSWER:
No, not
possible, because the energies associated with atoms is thousands of
times smaller than the energies associated with nuclei. Also, the
polarity of an electric charge (proton, for example) cannot change.
QUESTION:
My understanding of the nuclear fusion reactions, that are
to be the basis of proposed thermonuclear fusion reactors of the future,
is that a significant neutron flux is created? How is the structural
integrity of the walls of such toroidal reactors going to be maintained,
if bombarded by the neutron flux for extended periods?
ANSWER:
You have just hit on one of the many reasons why controlled nuclear
fusion has proven so difficult to realize. It still seems decades away
from realization. I have heard that it is generally accepted that the
containment vessels will have to be changed periodically. That is by far
not the most difficult problem faced.
QUESTION:
Is it possible to
manipulate magnetic fields? If so, how?
ANSWER:
Of course. If
you have a magnet and move it around you are manipulating the magnetic
field. If you have an electromagnet you can vary the current to vary
(manipulate) the field.
QUESTION:
Yesterday my manager came into
work with a cup of water that had frozen in his car overnight. There
wasn't a straw, or anything else, in the cup. But the ice, instead of
being flat, had what looked like a thin, inch-long shard of ice sticking
diagonally out of it. Also, the rest of the surface was kind of wavy,
like hardened lava. Why would a frozen cup of water make that strange
formation?
ANSWER:
This question has been previously answered.
QUESTION:
It is a simple question, but one that has great meaning
for me. I am PhD biologist retired and playing around in a new area.
Three bodies in a fixed volume have a fixed total momentum, distributed
in the first case evenly, (5, 5, 5), and in the second case unevenly,
say, (9, 5, 1). Are the collision rates the same? The answer I would
prefer to hear is that the unbalanced case has a lower collision rate,
though my instincts from Resnick and Halliday studied long ago fear that
the collision rate of the system is just a simple function of the total
momentum. Which? Use energy distribution instead of momentum
distribution if that makes things easier.
ANSWER:
An important
concept here is mean free path (L) which is the average distance a
particle travels before encountering a collision. The mean free path
depends only on the density of the gas (number of particles per unit
volume) and the size of the particles. Average time between collisions
will therefore be L/v where v is the average velocity of the particles.
(So collision rate would be v/L.) So, in your example, if the masses of
the three particles are the same, the average velocities would be the
same and the collision rates would be the same. So what you need to look
at is not the relative momenta but rather the relative speeds if the
masses are unequal.
QUESTION:
If the acceleration of an object
toward Earth is independant of it's mass, where is my logic wrong in
this hypothetical situation: Suppose there are two objects. One is a
golf ball. The other is an object the same size as the golf ball but
with significantly larger mass than the earth (say 1,000,000,000 times
the gravity of the sun). If you were to time the golf ball falling to
earth and the object falling to earth from the same height at the same
position in space, it seems they would not fall at the same rate. The
object of larger mass would pull the earth instead of the earth pulling
it. Since our reference point is the earth, we would see the object
"falling" to earth just like the golf ball. But because the
gravitational force of the object is many times greater than the
gravitational force of the earth, it would have a faster acceleration
than "g". So what I'm getting at is that from my limited understanding
of this stuff, it seems like mass is negligible only if the mass of the
falling object is NOT significantly larger than the object it is falling
"towards". But mass is not supposed to matter in a free fall situation.
Where am I confusing myself?
ANSWER:
Both objects will have the
same acceleration, g. The reason is that each particle experiences a
force F proportional to its mass m and each also has an acceleration
a=F/m so the acceleration does not depend on the mass. But, Newton's
third law says that in each case the earth feels an equal and opposite
force due to other object. But the acceleration of the earth toward the
golf ball will be unmeasureably small because the force is small and the
mass of the earth is big; so the earth will essentially sit still while
the ball falls. But the other object has a huge mass and so it exerts a
huge force on the earth; so the earth will accelerate "up" with an
acceleration much larger than the object accelerates "down", and comes
up to meet it. In each case, the object has the same acceleration but
the earth has different accelerations. It will therefore take a much
longer time for the golf ball to hit the ground than the heavy object
even though their accelerations are the same.
QUESTION:
The first
question is about pair production. Could you explain it in a very simple
(and yet on track) explanation for about the age of 13? The second
question is about the law of conservation of mass/matter. While the
universe is expanding, does this law apply? Why or why not?
ANSWER:
In future, please abide by the groundrules which stipulate single
questions. Second question first: There is no such thing as conservation
of mass/matter; in chemistry, it was one of the keystones: combine 16
grams of oxygen with 2 grams of hydrogen and get 18 grams of water.
However it turns out that this is not quite true because of E=mc2; some
energy is released when you burn hydrogen and this consumes a little
mass. However, the chemistry rule is very close to true for chemistry
because the energy released is tiny compared to the energy of all the
mass. But it is not true for nuclear fusion which is what fuels stars
like the sun and these stars get measurably lighter as they age. What is
true is conservation of energy for a system (including mass energy).
Your first question answer: Again we are dealing with E=mc2; if we
consider a photon (which is a little bundle of light), it has energy.
The shorter its wavelength, the more energy it has. For very energetic
photons, called gamma-rays, their energy might exceed the mc2 energy of
an electron plus a positron (the antiparticle of the electron, having
the same mass but opposite charge as the electron). If this is the case,
then it would not violate energy conservation if the photon suddenly
turned into an electron-positron pair. For example, suppose that we have
a 1.5 MeV (million electron volts, a unit of energy convenient for this
kind of problem, look it up!) Now, the rest mass energy of an electron
or positron is about mc2=0.5 MeV, so the photon could turn into a pair
and that pair would have, in addition to their mc2 energy, about 0.5 MeV
of kinetic energy. That is pair production. (By the way, this will not
happen spontaneously because a photon is a stable particle; instead you
must "tweak" it which is usually done by shooting the photons into a
strong electric field like that near the nucleus of an atom.
QUESTION:
im doing a project and im in 7th grade im trying to figure
out how to measure the energy someone uses during the hours of a day i
just dont know what the formula is to measure how much energy someone
uses do you know?
ANSWER:
As a 7th grader, you should learn
right now: physics is not about formulas, it is about thinking! Now, the
question you ask can never have an answer because it all depends on how
energy is used and what energy you want count in the your survey. For
example, if I drive a car I would need to know how many miles I drove,
what the energy content of a gallon of gasoline was, and how many miles
per gallon my car consumed. I will give you one fairly simple example
you can use if it is electrical energy you want to calculate. Most
devices are rated by specifying their wattage; for example, a 100 watt
light bulb comsumes 100 joules per second (a joule is a unit of energy).
So, if I burn a 100 watt light bulb for one hour I consume 100
(joules'second) x 3600 seconds =360,000 joules of energy. So your
formula is wattage x time (in seconds) = energy (in joules). A more
familiar unit of energy is the kilowatt-hour. One kilowatt-hour is the
energy consumed in an hour by a 1000 watt device (a kilowatt is 1000
watts) or 3,600,000 joules. If you look on your parents' electric bill
you will see that each month you are billed by how many kilowatt-hours
your household uses; a kilowatt-hour usually costs between 5 and 10
cents.
QUESTION:
I am a teacher (English teacher, though) writing
a program to help visualize relativistic effects for college students
(again, in English). I use it to help teach the Modernist worldview. To
be accurate, my program needs a very precise definition of the speed of
light. Apparently, the last time it was measured was in 1973, when it
was 299792.4574 km/sec. My question is: has current technology not
allowed us to refine this number to more decimals? I know that the
current accepted value is an integer, but that is because in 1983 the
uncertainty in the length of the meter was greater than the remaining
uncertainty in C, so the meter was based on the then-current definition
of C. But this doesn't touch the basic question of whether C has been
refined since it was measured in 1973. Can you tell me the best current
measurement of c in as many decimal places as possible?
ANSWER:
Well, here is some good news for you: the speed of light is exactly
299,792,458 m/s because the length of one meter is defined (since 1983)
to be the distance traveled by light in 1/299,792,458 s.
QUESTION:
why there is no net charge on gaussian surface?
ANSWER:
There is
no reason why there should be zero charge on a Gaussian surface. For
example, imagine a conducting sphere on which I have placed a certain
amount of charge. All the charge resides on the surface. If I say that
Gaussian surfaces are concentric spheres, then the charged surface is
one of them. Incidentally, any surface you choose to think about is a
Gaussian surface as long as it is closed, that is encloses some volume;
it just so happens that the most useful Gaussian surfaces are
equipotentials.
QUESTION:
What is instantaneous velocity,and can
you give me an aexmple using it?
ANSWER:
Average velocity is
distance traveled divided by elapsed time. Instantaneous velocity is
average velocity evaluated in the limit as the elapsed time becomes
zero. This involves differential calculus which is why Newton had to
invent calculus to do physics. If you are in a car which is speeding up
and you look at the speedometer and it reads 20 mi/hr right now, that is
your instantaneous velocity; a little earlier it was less, a little
later it will be more. For simplicity I have not worried about the
vector nature of velocity; I have assumed that travel is in a straight
line like a long straight road. Things get a little more complicated if
the path is not straight.
QUESTION:
Is the electromagnetic
spectrum truly continuous such that for any two given frequencies, no
matter how close together they are, there will always be another
frequency between them?
ANSWER:
In principle, the answer to your
question is a simple yes. In practice, there is a different answer. No
real electromagnetic wave is comprised of a single frequency. Because of
the uncertainty principle one needs an infinitely long wave to have a
perfectly determined wavelength, therefore frequency. Or one can say
that because of the uncertainty principle one needs to observe a wave an
infinitely long wave to have a perfectly determined frequency, therefore
wavelength. Real waves are of finite extent and therefore contain a
distribution of all frequencies. (Determining the details of the
distribution is called a Fourier analysis) However, you could have a
distribution which peaked at a particular frequency and another which
peaked at a frequency arbitrarily close to the first.
QUESTION:
This is somthing that has been getting to me for a while. If a long
level is built with a horizontal vial on each end and that level is
"calibrated" to work on the earth, will it work if I take it to the
moon. Regardless of the moons off-center center of gravity. I Think that
the curvature of the surface will be more sever and the distance to the
center will be close and this will cause the bubbles to be slightly
farther out from the center than they would be on Earth.
ANSWER:
You are correct if the length of the stick is not very small compared to
the size of the earth or moon. Otherwise, the effect will be negligibly
small.
QUESTION:
i know things don't fall faster at high altitude
but it feels like it because there is lower air resistance (right?). In
laymans terms, can you please explain to be why air is so thin at high
altitudes which makes things appear and feel like the fall faster - Im
things particularly in regards to skydivers - they seem to have a little
more trouble landing and guiding their chutes in higher altitude.
ANSWER:
When there is less air resistance, things will go faster. If
there were no air, the speed would continue getting larger without bound
(well, not to the speed of light or higher!) The less air there is the
faster an object will go before stopping its acceleration (called the
terminal velocity). So, your main premise is wrong�you don't just feel
like you go faster, you do go faster. The terminal velocity is also
dependent on the mass and, particularly, the geometry; the reason a
parachute works is because it has a lower terminal velocity than a rock.
Yes, at higher altitudes there is less air resistance so a parachute is
less effective; it would be useless if there were no air. The reason the
air thins out at higher altitude is as follows. There is a certain
amount of air in our atmosphere and, because it has weight, it arranges
itself in a layer over the whole surface of the earth. But, the deeper
you go into a fluid, the greater the pressure becomes; for example, when
you go swimming you can feel the increased pressure by the pain in your
eardrums as you go deeper. So, you are at the bottom of an ocean of air.
There is a big difference between water and air, though, since air can
be compressed and water cannot (for all intents and purposes), so the
higher the pressure the denser the air will be. Therefore the air is
dense at the bottom and gets less dense as you go up.
QUESTION:
If a spaceship leaves its engine on at full power, will it accelerate
forever? (assuming it has endless fuel)
ANSWER:
Well, a really
hypothetical question! Yes, it would continue accelerating but as it
approached the speed of light there would be less and less velocity
increase for each pound of fuel burned because the fastest possible
speed is the speed of light. So the energy would keep increasing but the
speed would hardly increase at all.
QUESTION:
I thought that
magnetic and electric field lines were just convenient representations
of how fields varied around charges and magnets, and, in reality the
electric field, for example, would vary continously with distance. If
this is the case, why do we see lines around bar magnets when sprinkled
with ion filings, or lines between parallel plates in castor oil when
sprinkled with semolina? What happens between the lines?
ANSWER:
You are right, the lines are just what we draw to convey what the field
is like, there aren't really lines. Let me talk just about the iron
filings around a magnet since both cases have a similar explanation
(polarization). Focus your attention on an iron filing: it becomes
polarized, that is it becomes a tiny magnet and it aligns itself with
the magnetic field of wherever it is. Now, look at its neighbors: those
near its ends will also be polarized but their N(S) pole will be close
to the S(N) of our first filing, and they like that; but those alongside
it will have their N(S) poles close to the N(S) poles of our first
filing and will tend to be pushed away. The net result will be chains of
filings separated from each other.
QUESTION:
I am an 8th grade
Earth Science Regents student, and I am doing a project on the effect of
the density of liquid on magnetism. The problem that I am having is that
I cannot calculate the force of the magnet. If the magnet is too strong,
it could pull out the object inside the liquid no matter what the
density of the liquid is, and no difference will be present between the
different types of liquid. How can I calculate the force of the magnet?
ANSWER:
You cannot calculate the magnetic field of a magnet, you
have to measure it. It depends on its geometry, how far you are from it,
what it is made of, how magnetized it is, etc. Do you have something
ferromagnetic inside your liquids? You need to experiment so that your
magnet is far enough away so that your sample will not be too strongly
attracted but enough to measure. Not to be negative, or anything, but
density is not the important quantity here but rather the nature of the
liquid itself; is it paramagnetic, ferromagnetic, diamagnetic, etc.?
Except for ferromagnetism, magnetic forces are very weak and you are
going to have trouble getting reliable results without pretty sensitive
equipment.
QUESTION:
When I go into my apartment in the winter, I
am full of static electricity. If I touch my metal closet door first, I
get an electric shock. I would rate this shock a "2" on a logarithmic 1
to 10 scale. However, if I first turn on the light, I get a shock that I
would rate a "3" on the same scale. I do not get shocked by my outlets
otherwise and I believe that I have the same static charge for both
events. Why is there this difference in the amount of shock? What is the
physics that causes additional shock? Is this related to what happens
with lightning?
ANSWER:
Electrical codes require that there be a
ground for all circuits, and this ground wire is connected to the metal
parts of the appliance, lamp, whatever. So, even though one of the two
leads to the "guts" of the appliance is also grounded, there is a
separate ground for everything which is not electrical. Your door is not
necessarily at ground potential. Also, the geometry of what you are
touching matters. The door is flat and the lamp presumably has a curved
surface; the electric charge on you hand induces a charge on the object
you are about to touch which is has a larger charge density on the
curved surface resulting in a greater potential difference. By the way,
if it is a logarithmic scale, the difference between 2 and 3 is a factor
of ten. Is that what you meant? For example, the Richter scale is
logarithmic and an earthquake with a Richter scale of 8 is ten times
stronger than one with a 7.
QUESTION:
what is a simple formula
for calculating the beam divergence of a white light flashlight.
Observationally it seems related to the ratio of emitter size to
reflector size. E.g, lights with a large reflector diameter (and/or
small emitter) seem to produce a more tightly focused beam. A WWII
searchlight with a huge reflector produces a very tightly focused beam
that converges for a long distance to a "beam waist", then diverges.
Details: Assuming a typical white-light focusing flashlight (e.g,
Mag-Lite) with a parabolic reflector focused to produce a
convergent/divergent beam, how do I calculate the smallest achievable
spot size (i.e, smallest beam cross sectional area) at a given distance?
How does this vary with reflector diameter, focal length, and emitter
source size? I can't just use angular field = arctan (source dia. /
focal length), as the beam can be initially convergent then divergent.
ANSWER:
Ah, the neverending quest for simple formulas for a
complicated world! There is no such simple formula Unless the source is
a point placed exactly at the focus of a parabolic reflector; you must
also ignore diffraction and any rays which exit without striking the
mirror. In any other case you would have to have to do detailed
raytracing which would require knowing the exact geometry of the source
and where on the source the focus of the paraboloid was. You would also
have to define criteria for quantifying what you mean as beam spot since
there will never be a clear-cut spot. This would, of course, be best
done with computers. Physics is not formulas!
QUESTION:
I teach
AP physics in high school and had a question concerning the electrons of
metals. What is the difference between the ionization energy of a metal
and its work function ?
ANSWER:
The ionization potential refers
to the energy required to remove an electron from an isolated atom.
However, the properties of most materials are affected by being in a
macroscopic solid, metals in particular. In a metal, the valence
electrons are, for all intents and purposes, free to move around, that
is they are already detached from the atoms of the metal. To remove an
electron from a metal, though, means that you leave behind a positive
charge which will attract the electron if you try to remove it, so it
takes work to remove an electron from a metal; this is the work
function.
QUESTION:
I know what Newton's first law of motion
means but could you give me some examples of it? And please make sure
they are comprehendible but good enough for a group of teachers.
ANSWER:
They are innumerable! I will give a few:
A spaceship is
sent to Mars. Once it has escaped the earth's gravitation and not yet
close to Mars, you do not have to keep burning your rockets to keep up
your speed; Newton's first law (N1) says that with negligible force an
object will move with constant speed in a straight line.When you stand
on a scale there are two forces on you, your own weight (the force the
entire earth exerts on you) and the force which the scale exerts on you.
Because of N1, the net force on you must be zero (you are at rest), so
the force the scale exerts on you must be equal in magnitude to your
weight but up. {To carry this a bit further, Newton's third law (N3)
says that the force you exert on the scale is equal and opposite the
force you exert on the scale and this is the force which the scale
registers. A scale does not measure your weight, rather it measures the
force you exert down on it which just happens in this case to be
numerically the same. If you are in an elevator accelerating upwards,
the scale will read something larger than your weight.}You are pulling a
box across a level floor with constant speed. The rope you are pulling
on is horizontal. The force with which you must pull is equal in
magnitude to the force of friction the floor exerts on the
box.
QUESTION:
is it possible to increase gravitational force at a
particular place or in a single room?
ANSWER:
The gravitational
force depends on the mass located near that place, so all you have to do
is put a huge block of lead under the room to increase the gravity. But
the gravitational force is so weak that you would be hard pressed to
observe any change since the mass of the earth is so large. I estimate
roughly that if you put a 10x10x10 m3 block of lead under your floor
that the weight of something in the room would increase by about
2x10-4%!
QUESTION:
A ruler with length lo is at rest in a
coordinate frame XY and tilt at an angle 45 degree. I know if paralell
the length is not the same for both frame and if perpendicular it has
the same length but what about the length of the ruler if it is at 45
degree? And how can i find the angle that i see between the ruler and
the direction of motion?
ANSWER:
The component of the ruler
along the direction of motion is shortened from (l0/√2) to
(l0/√2)√[1-(v2/c2)] while the component perpendicular remains (l0/√2).
You should be able to do the trigonometry from here.
QUESTION:
I
am a medical imaging student in PA. I asked this question in class and
was told not to worry about it, I wouldn't be tested on it, but I would
still like to clarify it in my mind. We were studying the difference
between characteristic and Bremsstrahlung X-rays. The text stated that
characteristic X-rays are dependent on the target material, tungsten for
most diagnostic X-ray machines and Mo or a combination of Rh and Mo for
mammography. The text further states that a characteristic X-ray occurs
when a K-shell electron is knocked out of it's shell and this requires
at least 70 KeV of energy and that no characteristic X-rays are produced
below 70 KeV and any less would produce only Bremsstrahlung. This makes
perfect sense to me when using a W anode, since the binding energy of
the K-shell electrons are 69 KeV. However, if the anode is made up of Mo
or Rh, the K-shell binding energy is around 20 KeV, so in a mammography
unit, wouldn't a 25 KeV setting produce characteristic X-rays? Or would
it only produce Bremsstrahlung X-rays?
ANSWER: (Thanks to Dr. Mark
Haidekker)
I hope the following answer is helpful to you: You are
"�correct in the assumption that characteristic X-rays are produced at
lower energies as well. Bremsstrahlung is emitted whenever a high-energy
electron changes its momentum. This is when it decelerates and some of
its energy is converted to photonic energy. The spectrum of
bremsstrahlung is broad. Conversely, when an electron or a X-ray photon
of sufficient energy moves an electron out of its shell into a
neighboring shell (excitation) or removes it from the atom entirely
(ionization), the vacancy gets filled eventually. This process frees
energy that gets released as an X-ray photon of exactly the binding
energy difference. The emitted spectrum is narrow, and it depends on the
atom. Therefore, it is referred to as characteristic X-ray radiation.
Characteristic X-ray radiation is not limited to the K shell, nor is it
limited to molybdenum or tungsten. If a K-shell vacancy of ionized
rhodium is filled, the characteristic X-ray energy will be 23 keV. An
electron dropping from the L- to the K-shell of rhodium would emit a 20
keV photon. A copper beam-hardening filter would produce scattered
X-rays of about 10 keV. However, any of these low-energy characteristic
X-ray energies would be absorbed: Either in the beam hardening filter
that can usually be found in front of X-ray tubes, or in the tissue
itself as the absorption coefficient of tissue is very high for low
X-ray energies. This is why beam-hardening is done in the first place:
If low-energy X-rays get absorbed in the patient's body, they don't
contribute to image formation, but they do cause ionization in tissue.
Therefore, low-energy X-rays get filtered out. In this context,
characteristic X-rays from molybdenum or rhodium would not pass the
beam-hardening filter, and low-energy emission would not be seen in the
spectrum emitted from a typical X-ray unit."
QUESTION:
I left a
bowl of water with three hard boiled eggs in the fridge and overnight
the top 1/2 in of water froze. The fridge is only around 38 degree F,
and nothing else in the fridge froze. Why did the water freeze? My
fiancee says it has to do with evaporation because the fridge is really
dry.
ANSWER:
I have answered questions before which involve
frost forming at temperatures above freezing. These involve both
evaporative cooling and radiative cooling, so your fianc�e has a good
idea. However, I really find it hard to believe that this could be the
answer to your question since a half inch of ice is a whole lot more
than a little frost and the temperature is so far above freezing. I
suspect a much more mundane reason: I have sometimes found ice on the
top of a bottle of milk but only if the bottle has been put in a
particular place in my refrigerator. Some locations of the refrigerator
are colder than others because of proximity to cooling coils, a duct to
the freezer section, or for other reasons having to do with how the
refrigerator is engineered. And, the temperature you suspect, 380, may
be inaccurate so that the whole refrigerator is set too low making it
even more likely that somewhere will be below freezing.
QUESTION:
we are trying to settle a debate at college. our questions regards the
4th dimension and its effects on ourselves in the 3rd dimension. the
question is as follows. when you are watching television, are you
watching something that happened at a different point in the 4th
dimension?
ANSWER:
Normally, the 4th dimension is regarded as
time. Physicists refer to "spacetime" indicating that time is on an
equal footing with space in relativity. So any two events which are not
simultaneous can be regarded as having happened at different "�point(s)
in the 4th dimension". It is interesting that different observers will
not agree on what is simultaneous, one of the important findings of
special relativity. Another way of saying this is that there is no such
thing as absolute time, a god-given clock right for everybody.
QUESTION:
In my physics class, we are only looking at one method of
pendulum movement, which is an approximation method depending on the
angle being very very small, but i was very curious about what its
function would be when the angle is larger. I tried figuring it out
myself, but i came across a problem that i have no idea what to do
about. Lets say we had a pendulum mass M, Length L, and distance from 0
of X (0 is the middle, where angle Z= 0) If we let it go from a certain
point, then the force upon it would be F= Mg[sinZ] (note, using Z
instead of theta for the angle made by the pendulum and vertical in
radians) Then Ma= Mg[sinZ] So a=g[sinZ] -- a=g[sin{X/L}] (radians
arc/length) ANd because in calculus acceleration is the second
derivative of the postion function (X) we get X''= g[sin{X/L}] Now here
is where i get lost, because i cannot figure out any way to find the
function X and i really need help for this... You could rewrite this as
f''(x) = sin[f(x)], to make things clearer as g and L are constants, but
i have no idea at all how to find the integral to get f[x] (function x)
and how to finish this to find a function that gives movement of
pendulums.
ANSWER:
Well, you are treading on some pretty
difficult stuff here. There are certain aspects of this problem which
can be solved using exotic mathematical functions called elliptic
integrals, but I suspect you don't want to go there. So let us just say
that this problem is one (as are most of nature's real problems) which
cannot be solved in closed form in terms of standard mathematical
functions. That is, y"+sin(y)=0 is not a differential equation which can
be exactly solved. But if we approximate sin(y)≈y, as you have learned
in your physics class, it can be solved. But, now you want to do better
than that. So you have to use a better approximation for the sine
function. Where did the first approximation come from? It came from a
series expansion for the sine, sin(y)=y-y3/3!+y5/5!-� So, if y is not so
small a better approximation would be sin(y)≈y-y3/6. Now you will find
that the period is better approximated by T=T0(1-(A2/8))-1/2 where T0 is
the period in the small angle approximation and A is the amplitude in
radians. For example, if A=900=π/2, T=1.2T0, about 20% longer. I should
warn you that, unless you are pretty handy with differential equations,
this is not trivial to deduce. In this day and age, one can solve
problems of this type numerically on a computer.
QUESTION:
I try
to move a very large boulder here on Earth. If I try to move the same
boulder on the moon would it take more force, less force, or would it be
the same force. I say same force, because it has the same mass. F = ma.
Makes since to me, but my students don't buy it. Any other possible
explainations?
ANSWER:
Perhaps what is bothering your students
is that friction has not been included in the discussion. In fact, why
are you often unable to move a boulder at all here on earth? It is
because the static friction between the ground and the boulder is larger
than the force you are able to exert. Indeed, the friction is
approximately proportional to the normal force which is in turn
proportional to the weight, so you might very well be able to move a
boulder on the moon which you could not move on earth. However, the
lesson you are trying to teach is an important one. So, ask your
students to imagine the boulder being placed on a cart on a track with
negligible friction on both the earth and the moon; if you exerted a
force the same on each, each would move identically. In fact, if you
went to the middle of empty space where there was no gravity at all, the
boulder would move just the same. This confusion arising from having
systems which are complicated by many factors such as omnipresent
friction was one of the major impediments to progressing from the
Aristotelean view to the Newtonian view of nature.
QUESTION:
What
is the relationship between an electromagnetic field or wave and a
photon? What is the distinction between a wave and a field?
ANSWER:
Electromagnetic (EM) waves are time varying electric and magnetic
fields. An EM wave is normally characterized by a frequency f, a
wavelength λ, a speed c, and an amplitude usually specified by
specifying the maximum electric field value. It was discovered in the
early 20th century that sometimes an EM wave will behave like a stream
of particles called photons. (You might want to research the
photoelectric effect and Compton scattering to see the historical
origins and verifications of this discovery.) This type of duality turns
out to be pervasive for all of nature, in particular a thing we have
always thought of as a particle (an electron, for example) will behave
like a wave if we design an experiment to look for wave properties. It
is a true feature of nature and physicists and philosophers refer to it
as the wave-particle duality. For EM waves, the amount of energy which a
photon has turns out to depend on the frequency of the radiation, E=hf
where h is Planck's constant. A photon is a special kind of particle in
that it has no mass.
An EM wave is, as I said above, time varying
electric and magnetic fields which propogate through empty space (unlike
most waves) and has a speed which is independent of the speed of the
source or observer, independent of the frequency or wavelength or
amplitude of the wave. So all EM waves are fields. However, all fields
are not waves. For example, there is an electric field around an
electric charge but it is not a wave if the charge is at rest or moving
with a constant speed; and, there is a magnetic field around a current
carrying wire which is not a wave if the current is steady.
QUESTION:
Some of my friends and I recently moved to St Louis, MO.
We have all independently found that twist top bottles, no matter where
they are originally from, are somewhat difficult to open. We have been
told that the center of the continent and the center of mass of the
continent are nearby and that St Louis or the surrounding area used to
be a huge exporter of lead. Does any of this explain this weird
phenomenon? Do nearby dense areas have an effect on torque? If so, would
this translate into the tightening of a twist top bottle over time?
ANSWER:
You're jokiing, right?
QUESTION:
My students hear
all the time that there is ZERO G. I tell them that astronauts are free
falling, like someone jumping out of an airplane. But I hear
professionals say zero G all the time and the kids are confused. How do
explain that gravity exists everywhere, and then they hear of zero g on
the space station ?
ANSWER:
First, let me say that your example
(which I have not included here) is not a good one. Let me attempt to
give an answer to the question regarding zero-g (sometimes referred to
as weightlessness). Those terminologies are, strictly speaking,
incorrect. What is your weight? It is the force which the earth exerts
on you. It is not what is measured by a scale; a scale measures the
force you exert on it, not the force the earth exerts on you. Of course,
in every day life the force which you exert on the scale happens to
equal your weight, but if you are in an elevator accelerating up the
scale will read more than your weight. If you are in an elevator free
falling down, the scale reads zero but your weight is still the same. If
you say zero-g you imply that the gravitational field is zero but that
is certainly not true anywhere near the earth (except at that point
where the earth's and moon's gravity cancel). I presume that you have
taught your students about centripetal acceleration. Anything which
moves in a circle of radius R with speed v has an acceleration toward
the center of the circle of v2/R. A satellite in a circular orbit has
just the right speed such that this acceleration is equal to g so, as
you correctly state, it is the same as the free falling elevator�you
feel like there is no gravity. All this is standard physics.
Here is
another perspective: Einstein's principle of equivalence states that
there is no experiment you can do to distinguish whether you are in a
gravitational field or in an accelerated frame of reference (that is,
the freely falling elevator and having zero gravity are physically
indistinguishable from inside). So, if it looks like a duck and quacks
like a duck, we might as well call it a duck!
(One final note: Note
that I have ignored the tiny correction that if you are orbiting with
your feet "down" your feet have a slightly different acceleration from
your head.)
QUESTION:
What exactly is in light that makes it be
affcted by gravity? please give me a thorough informtion about what
light contains that is affected by gravity.
ANSWER:
See an
earlier answer.
QUESTION:
Assume an electromagnetic wave in
vacuo. From my reading, I infer: 1: that a photon is a single cycle os a
wave 2: that each change in the orbital level of an electron produces
one photon. 3: that the intensity of light emitted from a source is
governed by the number of atoms in which electrons are changing orbital
level 4: that the basic difference between "ordinary light" and lased
light is that in lazsed light the photons are brought into tandem as a
continuous stream (wave) of photons. 5: that the energy of the photon is
equivanent to the energy lost by the electron during the orbital
transition.
ANSWER:
As in your question below, a photon is not a
wave at all.truetrue (number/second decaying)essentially correct. The
waves (think of waves, not photons) are coherent, that is they are all
in phase with all the others.true, but I would say energy lost by the
atom rather than by the electron.
QUESTION:
Is there a fixed
relationship between the wavelength of a photon and its amplitude?
Electromagnetice waves are usually graphed as two perpendicular sine
waves. But I suspect that they must extend laterally to some extent. Is
the shape if viewed longditudinally known? Can to direct me to a site
that would dispaly such?
ANSWER:
A photon is a particle, not a
wave. So it does not have a wavelength or an amplitude in terms of
electric and magnetic fields. A photon has fixed energy so that if you
think about the wave which is equivalent to the photon, its amplitude
will be determined by how spread out in space it is, that is by the
uncertainty as to where the photon is.
QUESTION:
I have read that
according to Einstein's theory, if a person were able to travel at the
speed of light, they could stop time completely, and slow time (from
people on Earth's perspective) if they were to travel near the speed of
light. Also, I read that the greater the gravitational force, the slower
your biological clock would run. Why would scientists not utilize this
theory in humans to slow their biological clocks and thus allow them to
see a greater future? It is probably possible with certain machinery to
elevate the force of gravity within a unit.
ANSWER:
You are
breaking the rules! No questions about traveling the speed of light! I
can give you two reasons we don't accelerate humans to velocities near
the speed of light:
The energy it would take get you going to 99% the
speed of light is huge.Even if we were willing to invest the energy is
such an adventure, your acceleration would have to be so enormous that
your body would be crushed beyond all recognition.Similarly, you body
would not be able to remain uncrushed in a huge gravitational
field.
QUESTION:
If i have a superconductive wire and i attach a
positive electrode to one end and a negative electrode to the other end
there will be some measurable current through the wire. every time i
recreate this circuit within the same parameters the same current will
be read. not any current, only this current. if the wire were thicker
(assuming that the cross sectional area of the electrodes were increased
the same extent) , more electrons would be able to flow through the
wire. thus the current would become greater. if were to replicate this
circuit i would again read this same greater current, not any. to my
understanding a potential difference is increased when the ratio of
electrons to protons on the positive electrode increases or when the
ratio of electrons to protons in the negative electrode decreases, thus
the attractive force between the departing electrons in the positive
electrode and the immovable protons in the negative electrode would in
increase with increased potential difference. i acknowledge that my
conceptualization of potential difference mat not be correct, but if it
is why would placing a positive and negative electrode to either end of
a superconductive wire result in a potential difference of zero? would
the electrons not flow more quickly through a superconductive wire if
the attractive force between them and the positive electrode is greater?
ANSWER:
By definition the potential difference across zero
resistance must be zero. When you connect a power source across it, the
voltage across the terminals must drop to zero or else the wire must go
nonsuperconducting. I have answered this question many times. You might
be interested in searching through previous answers for superconductor.
QUESTION:
I have a few unanswered questions about gyroscopic
precession. I looked thought the archive but I haven�t found anything
that directly answers my question. I understand if you spin up a
gyroscope, put It down at an angle, its axis will precess around in a
cone. I further understand (and correct me if I am wrong about this)
that in a completely frictionless environment it will precess forever
around its center of mass. This strikes me as similar to a spinning an
object in space. Spin it once and it goes forever baring friction and
outside influence. However in the case of the gyroscope where does the
initial energy come from to start in precessing? Does it tilt slightly
more upon release thereby lowering its center of mass and make use of
some potential energy? Does the gyroscope itself reduce speed slightly?
If we assume one of these things is true than it would seem the energy
would have to go somewhere once the gyroscope stops precessing. For
instance say we built a half circular frictionless tack that is the
correct height such that it supports the gyroscope once it gets to it,
without lifting it. Now, when the gyroscope reaches the track it should
stop precessing because there is no longer a tilting force applied to
it. However if the gyrocope initially derived energy for precession from
a slight drop or a decrease in rotation, does the reverse happen? It
would seem that it could not rise back up because then it would then
have a tilting force again. Does the gyroscope gain rotational speed?
ANSWER:
Your question comes close to violating the "single,
concise, well-focused questions" groundrule! Let's start out talking
about translation instead of rotation. Suppose you have a particle
moving along with some momentum and then you apply a force which is
perpendicular to its momentum; the result is that the momentum changes
(its direction, not its magnitude). This is because of Newton's second
law which is often more useful in the form of force equals rate of
change of momentum than force equals mass time acceleration. For
rotational motion, Newton's second law takes the form that torque equals
the rate of change of angular momentum. The gyroscope will not precess
if there is no torque on it, that is, if it were in empty space, it
would not precess. Like in the case of the particle above, the angular
momentum changes its direction rather than its magnitude; the spin rate
stays the same but the spin axis changes its direction. If you were to
suspend the gyroscope so that there were no torque on it (as in
gyrocompasses, for example) it would not precess. Most of your questions
are sort of not answerable because you did not understand the basics
which I have tried to convey. The motion is actually more complicated
than it appears but is well-understood; it depends on the initial
conditions but usually includes small wiggles (called nutating) about
the precession which are usually damped out quickly by friction in real
systems.
QUESTION:
if one has a circuit containing a
superconductive wire with a certain cross section of area, there will
exist some measurable current unique to this cross section of area. even
though there exists no electrical resistance through the wire there is
still a definite number of electrons which can fit within the wire's
cross section of area, all traveling at some velocity. how does a
definite number of electrons unique to a given cross section of area all
traveling at the same velocity not result in some definite current
unique to a superconductive wire with this cross section of area?
ANSWER:
What makes you think all the charge carriers would have the
same velocity? Your argument could equally well be made for a normal
conductor. In fact, all the charge carriers are in motion and the faster
the average motion the larger the current.
QUESTION:
If I sent
you in a spaceship to Alpha Centauri or say, Vega, and spun you in a
circle, how would you reliably return to Earth? Since those are
relatively close, what about the center of the Milky Way? I'm basically
asking, since you would be at a different point in the universe, how
would you reliably navigate back to Earth since the sky would look very
different? The difference might not be too great at Alpha Centauri, but
at say, the center of the Milky Way, I can't imagine how you would know
which direction you came from if you were "spun" around to face a random
direction once you got there.
ANSWER:
You underestimate the
power of computers in the current state of celestial navigation. All you
need to know is the position (say relative to the sun or maybe relative
to the center of the galaxy) of as many recognizable stars as possible.
Then any even modest computer could easily calculate how those stars
would appear to you as seen from anywhere.
QUESTION:
I understand
that when an atom makes a transition from one state to another it emits
a particle of light called a photon.. well now, is the photon in the
atom ahead of time that it comes out? or is there no photon to start
with? and if there is no photon to start with then where does it come
from and how does it come out??
ANSWER:
Let's first discuss a
radio station. The way we broadcast the radio waves is that we cause
electrons to move back and forth in the antenna. These wiggling
electrons cause the waves to be emitted from the antenna. Did these
waves exist before we started wiggling the electrons in the antenna?
Were they somehow sitting there waiting to be sent off? No, of couse
not. The wiggling electrons created them, not from nothing but using the
electrical power we put into the wiggling electrons in the antenna. For
example, if we put 50 kilowatts into the antenna, then 50 kilowatts of
radio waves will come out of it. Now to your question. The excited atom
is like a little antenna; when the atom drops to a lower energy state
the electron has to change the way it moves in the atom, sort of by
wiggling into the new state. But the atom lost energy equal to the
difference between the two states, so electromagnetic energy is radiated
away, the photon which is the smallest possible bundle of
electromagnetic wave.
QUESTION:
What is meant by " Protons
gyrating at very high magnetic fields"?
ANSWER:
I have not this
expression before. It probably refers to the precession of the proton's
magnetic moment in the magnetic field. This is just the same as a top
which precesses in the earth's gravitational field. I can't say more
than that without knowing the context of the quote.
QUESTION:
i
understand that all is always in motion & therefore
changing/transforming/decaying. My question is what does gold change to?
ANSWER:
I have no idea what you are talking about. Just because
something is in motion does not mean that it is
"changing/transforming/decaying". A passing car is in motion but not
changing into something else. Gold is a stable element and does not
change into anything.
QUESTION:
Given a circuit comprised of
superconductive material and a known voltage how could the current be
calculated?
ANSWER:
I have answered this question a couple of
times before. What it boils down to is that if the resistance is zero
the potential difference is zero. You simply drain the power source by
shorting it out. The current can be anything and the voltage must be
zero.
QUESTION:
We have just started a physics project and I was
wondering if you could offer a little help. Our teacher hung a
remote-controlled plane from the ceiling by a string. He turned it on
and waited until it reached a constant velocity (it travelled in a
circle). Then he timed how long it took for the plane to complete 15
revolutions. Our job is to find out how long it took for this to happen.
We are allowed to take any measurement we want execpt for measuring the
time. The mass of the plane is 29.6g. The length of the string is 2m
90cm. The radius of the circle in which the plane travelled is 2.37m.
I'm not asking for an answer for this project but I was wondering if you
could give me some ideas and inspire me. Heh heh. Every time I try to
plug it into one of our distance, acceleration, momentum, etc. equations
I hit a dead end. I have an idea about using the angle that the string
was at to somehow play into this.
ANSWER:
This pretty much
sounds like homework, so I cannot tell you how to do it. I will give you
a hint: the vertical component of the tension in the string must be
equal to the weight of the plane. Look up the analysis of the spherical
pendulum. Incidentally, you should not say that the plane has constant
velocity, it has constant speed. Velocity is a vector and since the
plane's direction is constantly changing its velocity is constantly
changing.
QUESTION:
My friend received a speeding ticket a long
time ago on a motorcyle. He says it was for a speed much faster than he
was ever going. He says a knowledgeable person told him that the false
reading was due the the motorcyle wheel spokes going faster than the
speed of the motorcyle, or the velocity of the spokes adding to the
motorcyle speed. Its been a while since I took a basic college physics
class, but it seems to me that the if the bike is going speed X, the
circumference of the tire - the part that contacts the road, has to be
going the same X. If the tire tread is rolling out at a velocity of X,
any spoke - being less far from the axle, has to be going less than X.
EG, the spoke cant be going faster than the speed of the bike. Is it
physically possible parts of a motorcyle wheel can indicate on a radar,
a speed that is faster than the actual speed over ground of the
motorcyle?
ANSWER:
The axel of a wheel goes forward with the
speed of the vehicle, the bottom of the wheel is at rest, and the top
goes forward with a speed twice the speed of the vehicle. Any particular
spoke might have a forward speed anywhere from about zero to about twice
the vehicle speed depending on where you look. I would say that the
likelihood of the radar reading the speed of a spoke is virtually zero.
Either your friend was mistaken about his actual speed (likely) or the
radar malfunctioned. The speed of the spoke argument is not likely to be
the explanation.
QUESTION:
My question is about light. If light
is affected by gravity, what is in light that makes it be affected like
any other matter? I know that light is affected by light because they
are pulled into blackholes. Try to make two answers....one answers for a
6th grader (easy) and one for a teacher level (confusing).
ANSWER:
I have answered this question previously. The answer has a part geared
toward an 11 year old and another from the perspective of warping
spacetime.
QUESTION:
why does it become significantly easier to
balance a bike the faster you are going (either pedaling it or say going
down a hill)? For instance, it would be very difficult to balance on
your bike if it was standing still, less difficult when you first start
to pedal away, and even less difficult when you get some speed. I can
balance with no hands best when my bike is moving swiftly. Why is it
that the additional speed results in easier balance? And is there a
point of diminishing returns, like a point at which the additional speed
doesn�t help you but hurts your balance? Let�s assume for all of this
that we are on a �good road,� i.e. you aren�t trying to balance your
bike on a rocky trail or something.
ANSWER:
This is actually a
tricky question and one which requires more space than I can give to a
single answer. The glib answer would invoke the gyroscopic behavior of
the spinning wheels but, although this is often cited in elementary
physics classes as an explanation for steering a bike it turns out to be
a very small part of the explanation of bicycle stability. Here are two
sites where you can get a pretty lucid explanation:
http://en.wikipedia.org/wiki/Bicycle_and_motorcycle_dynamics
http://socrates.berkeley.edu/~fajans/Teaching/bicycles.html
Or, you
can do a google search on physics of bicycle.
QUESTION:
Particle
accelerators take up alot of space, would it be possible to make them
take up less space by making them in a dense curled corkscrew shape?
ANSWER:
A particle with extremely high energy is extremely hard to
deflect from a straight path. Even using the strongest magnets available
(superconducting magnets) only a modest deflection of the passing beam
of particles can be achieved. So it is simply not possible to bend them
around a closed path in a very small space. An interesting detail is
that once you get very close to the speed of light, the magnetic field
does not have to be adjusted to compensate for the greater energies as
the particles gain energy; a magnet will bend a 500 GeV proton just
about the same as a 1000 GeV proton, so you can use the same path for
the particle as it is accelerated. The accelerator does not really
accelerate the particle much at all as the energy increases (like a
proton traveling at 99.9999% the speed of light would have a much higher
energy than one with a speed 99.999% but almost the same speed). So
accelerators would be better named energizers than accelerators!
QUESTION:
how much percentage of light would be lost if light (say a
flash light) was shot into a box with the dimensions of 1ft. by 1.ft by
1 ft., filled entirely with the best reflecting mirror found in the
world?
ANSWER:
All of it, and very quickly. See an earlier
answer to get a perspective on how fast the light would be lost.
Incidentally, the light is not really lost but is converted into thermal
energy when it is absorbed by the mirrors.
QUESTION:
What
effects would we feel if a black hole approached the earth? What would
happen to our orbit around the sun and the moon's orbit on us?
ANSWER:
That depends entirely on how massive the black hole is and
how closely it approaches. If the earth were inside the event horizon,
it would be swallowed up.
QUESTION:
As I understand the Quantum
Mechanics double slit experiment an electron (or photon) is shot through
a wall with two slits. If there's an observer (which I understand to
mean any force that impacts on the experiment's system) then the
electrons hit photoelectric paper as if the electrons were particles, in
other words they hit in one and only one place. If there isn't an
observer they hit as a probability wave. My question is, why isn't the
photoelectric paper considered an "observer" since it clearly interferes
with the system, in fact it's there to observe the behavior. Given my
limited understanding of the Quantum Eraser experiment I don't see why
time should have an impact on the recording of the electron's hitting
the paper.
ANSWER:
You do not have it quite right. It is not "if
there's an observer" but rather whether the observation makes a
measurement which tells you which slit the electron (or photon) passed
through. If you make this determination, the interference pattern does
not appear.
QUESTION:
a single photon of red light does not
possess sufficient energy to remove an orbiting electron from its
nucleus. in theory, if more than one photon were to contact one electron
(of course quite an improbable scenario) could the combined energy of
the photons potentially cause ejection of the electron?
ANSWER:
Yes, it is called multiphoton ionization. It is practicable with
high-intensity lasers.
QUESTION:
I am holding a 20 newton object
at arms length a constant 1.5 meters above the ground. My body will
clearly be expending energy to maintain the object at that height. How
do I calculate the rate of energy expenditure (power) required to hold
the object at the specified height? This problem is vexing to me,
because the same object could be placed on a stationary 1.5 meter
platform to accomplish exactly the same thing, but the platform will
obviously not have to expend any energy. I am having trouble
understanding exactly how these scenarios differ.
ANSWER:
This
energy which you perceive as being consumed is not going into the object
you are holding up. There is no work being done on it. I agree that some
chemical energy will be used by your body to achieve this, but there is
no way to calculate this since it depends on the individual's fitness,
metabolism, etc. The energy expended would end up in thermal energy and
would be used for the biochemical reactions necessary to maintain the
required tension in the muscles.
QUESTION:
When two objects come
into contact (say my buttocks and a wooden chair) does an exchange of
matter occur between the two? If so, what gets exchanged? Do they, for
example, exchange electrons?
ANSWER:
Yes, of course. Untold
millions of atoms go both ways. But millions is a really small number
compared to the total number of atoms in the objects (like on the order
of 1024). But, ultimately this is why clothes get dirty, clothes wear
out, things have to be repainted now and then, etc. Also, electrons can
go one way or the other which is why you sometimes have a static charge
on you after rubbing on something.
QUESTION:
If a free electron
interacted with a photon (in a vacuum if it helps), what would happen?
For example, would the photon reflect off the electron, or does it
depend on the motion of the electron?
ANSWER:
It depends on the
energies of the electron and photon. If their combined energies are high
enough then production of elementary particles could happen. For
example, the photon could convert into an electon-positron pair. I
suspect that is not really what you are asking, though. Regardless of
the energies, the most likely interaction is simple elastic scattering,
the photon and electron have the same total energy and linear momentum
as before the scattering but move in different directions than before
with different shares of the energy. The best known example of such
scattering is called Compton scattering. This is probably what you refer
to as "reflect off the electron".
QUESTION:
1. Using a conversion
factor such as (12inches/foot), the conversion factor is equal to what?
2. How to convert mm to meters? 3. How to convert ms to seconds? 4. How
to convert cm to meters?
ANSWER:
The key is to multiply by 1 so
the units come out the way you want them. For example, suppose you
wanted to convert 73 miles to centimeters: 73 mi(5280 ft/1 mi)(12 in/1
ft)(2.54 cm/1 in)=73 x 1.61 x 105 cm =1.175 x 105 cm; note that each
quantity in parentheses is 1 even though it is numerically not 1. The
ones you ask for are easier: N mm(1 m/1000 mm)=N/1000 m; N ms(1 s/1000
ms)=N/1000 s; N cm(1 m/100 cm)=N/100 m.
QUESTION:
I'm trying to
see I have the right "image" in my mind of how photons work,
specifically in the photoelectric effect. Suppose someone was trying to
free electrons from a metal by using light. Would this mean that even
though an individual photon can have a range of energies the amount of
photons must be an integer number? The "image" in my mind is someone
trying to break a window by throwing an (integer) amount of small
projectiles, but he has the choice of rocks or ping pong balls. He could
use a thousand times more energy throwing a million ping-pong balls at
the window, than using a single rock, but the single rock will break the
window (minimum frequency can release an electron) while throwing ping
pong balls does nothing (does not release an electrons).
ANSWER:
I guess your visualization is ok. Your ping pong balls would represent
photons with energy smaller than the energy required to remove an
electron. Your rock would represent a photon which does have enough
energy.
QUESTION:
I teach third grade and students have built a
ramp and are using a toy car without mass and with mass to see if the
distance increases with mass. The car should go further, correct? But
why in third grade terms.
ANSWER:
I have addressed this question
twice before. If you read those answers you will find that yours is not
a simple question easily answered in terms of basic physical laws. There
are too many complicating factors and friction is not nearly as clean a
topic as it is often represented in elementary physics textbooks. I am
assuming your ramp takes the car down to a flat surface. If there were
no friction, the loaded and unloaded cars would move exactly the same
and would keep going forever. If the friction were proportional to the
weight, (which is what an elementary physics textbook will tell you) the
two cars would still move identically and go the same distance before
stopping. So, this experiment is a good example of an experiment you can
do to see if the simplest physics works. If not, tell your kids that
what scientists do all the time is test accepted theories and when those
theories fail the scientists try to figure out why. Since you are using
the same car for both tests, I would think they would go about the same
since the friction should roughly double if you double the weight.
QUESTION:
Doesn't a photon have to have a mass equal to its energy
divided by the speed of light squared?
ANSWER:
The trouble with
having a well-known equation like E=mc2 is that it is often used when
not appropriate. If you write E=mc2, then this is the energy of a mass
which is at rest; or else it means that the mass has a different meaning
from what you usually think of when it is moving with speed v, namely
m=m0/√(1-(v2/c2)) where m0 is the mass of the particle at rest, what you
usually think of as inertial mass. As I have said in many earlier
answers, I prefer to not think of mass as increasing with velocity, m to
me just means rest mass. The correct equation for energy is
E=√(p2c2+m2c4) where p is the linear momentum. So, if a particle is at
rest, momentum is zero and E=mc2; if the mass is zero (as is the case
for a photon), E=pc. So a photon has momentum even though it has no
mass. One thing to be careful of, as explained in my earlier answers, is
that momentum is no longer mv but rather mv/√(1-(v2/c2)).
QUESTION:
Has the superstrings theory been discarded?if yes why if not then what
are these strings made of?
ANSWER:
String theory is still a very
active area of research. However, many physicists, including myself, are
not attracted to a theory which cannot make any predictions about nature
which seems to be the case with string theory. It is not an appropriate
question to ask what the strings are made of; supposedly everything else
is made from them.
QUESTION:
A classic paradox in Greek
philosophy is the paradox known as "Zeno's Paradox" which involves the
race between Achilles and the Tortoise. According to this paradox,
Achilles must traverse an infinite number of points to overtake the
Tortoise, which is physically impossible and yet he does in fact
overtake the tortoise. Hence the paradox. Most people have thought that
the concept of "Limit" in calculus has solved this paradox, but
apparently such solutions don't do justice to the paradox in it's
original form. (See the entry on wikipedia on Zeno's paradox). It has
been suggested that the correct solution comes from Physics directly. In
other words it is better to consider that space-time is not infinitely
divisible but is rather essentially discrete and that motion is actually
a series of jumps from one quantum space-time coordinate to the next.
This solves the Paradox since now Achilles actually traverses a finite
series instead of an infinite one.
ANSWER:
I don't think any
serious logician finds anything paradoxical about Zeno's paradox. There
is no need to discretize space to get a more satisfactory explanation.
If we assume space is continuous there is still no problem understanding
why the fast catches up with the slow. However, the question of whether
or not space is in fact continuous or discrete (as well as time) is an
open one and of interest to physicists, particularly those studying
quantum gravity. I have previously answered a question similar to yours.
QUESTION:
An ideal gas is inside an insulated container so heat
can't escape. If the cas is compressed, according to the first law,
internal energy is increased so temperature increases - am I right? If
so, why does the temperature increase? The temperature relates to how
fast molecules are moving. I am thinking that if they hit against a
piston coming at them, they will rebound faster - am I right? This would
explain the temperature decrease if the gas expands If I am right, I am
thinking that if the piston is moved very slowly compared to very fast,
I would expect a different final temperature - am I right? Also, why
does gravity seem to have no effect on molecules. If gravity has any
effect at all, I would expect all the molecules in the container to
eventually end up at the bottom of the container if is left alone for a
very, very long time.
ANSWER:
The first law is energy
conservation. If you arrange so that no heat goes in or out of the gas,
then the work done on the gas must equal the increase in energy of the
gas. This is called an adiabatic compression (AC). It may be shown that
for AC the pressure and volume are related by PVγ=constant where γ=Cp/Cv
and Cp and Cv are the specific heats of the gas at constant pressure and
volume respectively. The work done on the gas when you go from P1, V1 to
P2, V2 is W=(P2V2-P1V1)/(γ-1). One can easily relate this to the
temperature change because work may also be written as W=Cv(T2-T1). All
the details can be found in any introductory physics textbook. Your
qualitative analysis of the moving piston speeding is the gas molecules
is a good one. There is no reference in my remarks above about how you
get from 1 to 2, so your expectation that the temperature change depends
on how rapidly your compress the gas is not right; when you go slowly
you give the molecules many little kicks but when you go rapidly you
give them a few big kicks. In the real world we usually want the
compression to be fast to guarantee that it is adiabatic because it is
hard to make a really well insulated cylinder so if you compress slowly
heat is more likely to leak out as the gas heats up. But, if it is well
insulated it should make no difference. Regarding gravity, it does have
an effect but, because the molecules are restless (they can't all settle
at the bottom because they keep moving around if the temperature stays
constant), the effect is smaller than you expect. In fact, the density
of gas at the top of a container is very slightly smaller than at the
bottom. You might find this difficult to believe, but it happens for the
same reason that the density (pressure) of the air decreases with
altitude.
QUESTION:
I just emailed you some very basic questions
about thermodynamics. One of them was why gravity doesn't cause all
ideal gas molecules to evetually settle at the bottom of the container.
I am thinking now that this may be due to the temperature of the walls
of the container. Since the walls are at the same temperature, maybe the
motion of molecules in the walls excites the gas and keeps that from
happening. I feel like these are all dumb questions because they seem so
basic - yet I don't remember these questions being answered in school,
although it has been a long time.
ANSWER:
Your questions are
not dumb. When we derive the ideal gas law we assume that the collisions
of the molecules with the wall are elastic, that is no energy is lost or
gained in a collision. This is not necessarily true for any given
collision but, if the gas and the walls are in thermal equilibrium, it
will be true on the average, just as many collisions gaining energy from
the walls as those losing energy. When you are dealing with something
like 1024 atoms, the average is what matters, not one particular event.
QUESTION:
On Saturday I visited my sister in freezing eastern
Pennsylvania and I noticed a strange ice formation in her outdoor
birdbath, which is currently frozen due to subfreezing tempertures. This
is a cheap 12 dollar birthbath, it is not heated. I would like to send
you a photograph of the gravity-defying ice formation and hope a
physicist can tell be what law of nature would cause water in a birdbath
to freeze up into a small column.
ANSWER:
This question has
been previously answered.
QUESTION:
I've never quite fully
understood the classic "bicycle wheel and spinning chair" demonstration.
Specifically, I've never understood the middle stage, in which the wheel
is rotated 90 degrees, rather than the full 180. At this stage, the
student should be rotating around a vertical axis in the same direction
in which the wheel was initially spinning (say, clockwise), with the
wheel's initial angular momentum. But the wheel is itself still rotating
(around a horizontal axis) with its full initial momentum. There seems
to be a new angular momentum vector, orthogonal to the system's initial
angular momentum and equal to it in magnitude, that was not introduced
by an external torque. What am I missing?
ANSWER:
Imagine that
you are in empty space where angular momentum must be conserved. You
start with angular momentum L0 which is parallel to your spine, say.
Later the wheel has angular momentum L0 perpendicular to the original
direction of your spine. So the change in angular momentum of the wheel
is in a direction 450 relative to the original direction of your spine
so that is the axis along which your angular momentum must have to
conserve angular momentum. When you do this experiment you should feel
like something is trying to push you off the stool but you can only
rotate about an axis parallel to your spine so angular momentum is not
actually conserved; the friction between you and the stool exerts an
external torque.
QUESTION:
They say that the blackholes'
gravitation is so massive that it devours light but the photon has no
actual mass so how is he attracted to the hole?
ANSWER:
Light is
affected by gravity just like mass. The reason it is not evident is that
light travels so fast. Imagine a baseball zipping by at near the speed
of light; you would be hard pressed to see at drop much as it zipped by.
It has been observed experimentally by observing the bending of distant
starlight as it passes close to a massive object, for example the sun
during a solar eclipse. This is all understood in the theory of general
relativity where the explanation of gravity is that massive objects
actually warp the space around them and when light is bent by gravity it
is simply following a "straight line" in this warped space.
QUESTION:
What is heat or thermal energy on the atomic or sub-atomic
level? Is it the nucleus spinning or perhaps the nucleus is bouncing
around relative to the electrons? Do we even know or have theories?
ANSWER:
First of all, heat is energy transfer, not energy content.
For example, heat flows from a hot object to a cold one but you do not
say that the hot object has more heat than the cold one. If we refer to
the internal energy of something, for example a gas, it is the average
energy per constituent; it is this average energy which temperature
measures. In a gas this is the average kinetic energy per molecule. So
let us define thermal energy as average energy per constituent. Then in
a nucleus the average energy per nucleon is the "thermal energy". A
"hot" nucleus is a highly excited state.
QUESTION:
From a
previous question a basketball zipping by at a substantial percentage of
the speed of light will have its apparent shape change from sphere to an
oblate spheroid because of the shrinking along the direction of motion.
This will cause a decrease in its volume and surface area. If the basket
ball is replaced by a black hole will the decrease in surface area cause
a corresponding decrease in its entropy and mass?
ANSWER:
First,
it is wrong to refer to its "apparent shape". Relativity tells us how
things are, not how things appear to be. Length contraction says that a
meter stick moving by (parallel to its own length) is actually shorter
than one meter if we make a measurement of its length. (The operational
definition of length is to measure the positions of the two ends of
something at the same time.) Regarding entropy, I believe the article I
referred you to in the earlier answer showed that entropy, like
temperature, is not a useful concept in relativity. The mass is also an
ambiguous thing; many people simply envision mass as increasing with
velocity, but in many earlier answers I have argued that one may simply
say that rest mass is the useful concept and momentum is no longer
defined as mass times velocity.
QUESTION:
If a basketball zips by
at a substantial percentage of the speed of light will its shape still
be a sphere or will the length contraction in the direction of motion
cause the shape to change? If the shape is different would the volume be
the same or would it change and the pressure of the air inside change?
ANSWER:
The diameter of the ball along the direction of motion will
get smaller so the ball will not be a sphere. The volume therefore gets
smaller as measured by an observer seeing it zip by. The volume will be
reduced by a factor of √(1-v2/c2). That is the easy part of the
question. The question concerning the pressure is a very difficult one
and I have not found anybody who can give me a definitive answer. I have
done a little research and have found more information about temperature
than pressure in special relativity. There is a what is called the
Planck-Einstein transformation for temperature: the temperature of the
gas in the passing ball is reduced by the same amount as the length,
that is √(1-v2/c2). So if we now assume that the ideal gas law, PV=NkT,
is correct in the moving system, then if V'=V√(1-v2/c2) and
T'=T√(1-v2/c2), it follows that P'=P; the pressure is unchanged. That is
all well and good, but recent research has shown that the
Planck-Einstein transformation is incorrect. In fact it appears that
there is no Lorentz transformation for temperature which essentially
means that temperature as we define it is not a useful variable in
relativity. I suspect that the same could be said for pressure, that is
it is not a variable which we could transform into a moving system,
there would not be a way you could measure pressure in your moving ball.
That is the best I can do with this question. If you get a better answer
somewhere, I would be most interested in learning what you learn.
QUESTION:
My husband and I are having a disagreement on the energy
used to air dry laundry indoors. He argues that it is less energy
efficient than, or at least the same as. running the gas dryer, to air
dry laundry indoors in winter because then the house heating system has
to work harder to convert the water molecules in the clothes to liquid
and gas. I don't have a good answer for him, but it just seems
counter-intuitive. It seems like the air drying clothes are at the same
temperature as the surrounding air, and don't need heat to "wam up" the
water in the clothes. It also seems like the water in the clothes would
evaporate due to the dry air (some mumbo jumpo about liquid/vapor
equilibrium), not because of heat energy being transferred to the
molecules. He doesn't deny that air drying provides moisture to the
room, his argument is that the energy required to evaporate the water
ultimately comes from the furnace so we might as well run the humidifier
and the gas dryer. What do you think?
ANSWER:
Your husband is
not going to like this, but he is dead wrong. You could turn your
furnace off and your clothes would dry just about as fast. Certainly air
drying clothes takes energy from the environment, but the amount is
trivial compared with how much your furnace needs to put out to keep
your home warm. Believe me, your furnace will never notice. Yesterday it
was about 35 degrees at my house and I hung out clothes which dried in
about 2 hours. Clothes dryers are among the biggest energy hogs of all
our appliances because so much of the energy goes out the exhaust or
heats up the dryer drum or just leaks away in some other way. When I
started hanging out my clothes instead of putting them in the dryer my
electric bills went down about $20 per month. Here is another thing (ok,
this is kinda off the wall!): if you dry your clothes in the house it
will humidify your house which makes it feel warmer so you can actually
turn the furnace down!
QUESTION:
How can Bob who lives in a 2
dimensional world (a) discover the 3rd dimension (b) imagine the 3rd
dimension?
ANSWER:
This is a pretty open-ended question. Let me
give one example. In some respect you live in a two-dimensional world
because you live mostly on the surface of the earth. If you did not
understand that your two dimensions were embedded in a three-dimensional
space you might be inclined to think that you were on a big flat plane.
But, if you started walking due west you would eventually get back to
where you started from and you would start thinking maybe there were
higher dimensions.
QUESTION:
Simple: All mass gives off a
gravitational field. The more mass the stronger the field as well as the
greater it's area of effect. Density is the amount of matter in a given
space. So my question is: If you take all the matter in the Earth and
increase it's density by two will the gravitational field effect space
and matter the same as at normal density or will the area of effect half
it's size while it's gravitational field strength doubles? This ratio is
off the top of my head but an equation with explanation of the variables
if ones exists will suffice.
ANSWER:
What you describe will
double the mass of the earth. The result will be that the gravitational
field due to the earth will double everywhere. I do not understand what
you mean by "...the area of effect...". The gravitational field extends
to infinity regardless of its strength.
QUESTION:
What does it
mean when a field is represented by 2nd-rank tensors (Einstein's
gravity)? If a scalar (0-rank) is a numerical quantity representing
magnitude, and a vector (1st-rank) is a magnitude that has a direction,
then is a matrix (2nd-rank) a plane represented by orthogonal vectors
(squared magnitude/perpendicular directions)? Have 3rd-rank tensors ever
been used in any physical theories?
ANSWER:
This is really too
technical a question for the purposes of this web site. I can tell you
that a physically observable quantity may be characterized by how it
transforms under certain tranformations; examples of transformations are
translations, rotations, space reflection. If you are doing physics in
an N-dimensional space then you need one number to specify a scalar
quantity, N numbers to specify a vector, N2 to specify a tensor
(although symmetry proporties usually reduce this number, maybe
something like Tij=Tji), etc. I do not know how to answer the question
"what does it mean", it simply is what is mathematically necessary to
describe accurately something in nature. An example more accessible than
gravity is perhaps electromagnetism. Here we may describe the
electromagnetic field by specifying two 3-dimensional vectors, the
electric and magnetic field; this requires 6 numbers. However, the field
may be alternatively represented by a single quantity, the field tensor,
also containing six numbers but having the elegance of a single quantity
rather than two.
QUESTION:
I was reading the short article:
Scientists Expose Light's Wierd Quantum Nature, #65, pg 56- Discover
Magazine-The Year In Science-Jan 2008. Isn't Light's quantum nature
fairly obvious taking the macro approach? For instance...if two planets
were one light year apart...and planet A flashed a bright light at
planet B...wouldn't the guy on planet B be able to look through a (very
powerful) telescope focused at 1/4 the distance in three months and see
the same flash that he would be able to see three months later by
focusing at 1/2 way point, and three months later focused at the 3/4
point? In other words, the same event would not only exist in an
infinate number of places at an infinate number of different times, but
given the spray effect over that far a difference, would exist at an
infinate number of focal points from an infinate number of points of
view...wouldn't it?
ANSWER:
Your telescope does not allow you to
observe someplace instantaneously as you assume. When you focus your
telescope at the 1/4 the distance point you see light which started from
there 9 months ago, not light coming from there right now. If you focus
your telescope there you will see your sought pulse in your telescope in
9 months. And so forth.
QUESTION:
A middle-aged man typically
has poorer hearing than a middle-aged woman. In one case a woman can
just begin to hear a musical tone, while a man can just begin to hear
the tone only when its intensity level is increased by 6.0dB relative to
that for the woman. What is the ratio of the sound intensity just
detected by the man to that just detected by the woman?
ANSWER:
Let D be the intensity in decibels and I be the intensity in W/m2. Then
the definition of the decibel gives Dwoman=Dman+10 log(Iwoman/Iman).
Then Dwoman-Dman=6 dB=10 log(Iwoman/Iman). So log(Iwoman/Iman).=0.6 and
solving I find Iwoman/Iman=3.98 .
QUESTION:
If you could lump all
of the atomic nucleuses in the human body into a ball, how big would it
be? Smaller than the head of a pin? About the size of a pea?
ANSWER:
The size of an atom is on the order of 10-10 m and the size
of a nucleus is on the order of 10-15 m. So, if we say the size of the
body is on the order of 1 m, the size of the nuclear matter in the body
would be about 10-5 m, about 1/100 of a millimeter!
QUESTION:
In
a nuclear reactor, what is the importance of particle speed in relation
to cross-sectional area?
ANSWER:
I am not sure what you are
talking about but have a rough idea, I think. In a reactor, the fuel is
induced to undergo fission by absorbing neutrons which makes the nucleus
unstable to fission. As luck would have it, when fission occurs several
neutrons are produced which may be used to induce still more fissions
(chain reaction). However, these neutrons are very fast and unlikely to
get absorbed before escaping from the reactor. Hence, to enhance the
probablility of these neutrons causing more fissions they must be slowed
down (moderation). Slow neutrons are likely to get captured and maintain
the chain reaction. So where does the cross section part come in? It
turns out that the probability of neutron capture is related to a
quantity called the neutron absorption cross section and, as should be
evident from the discussion above, the cross section increases as the
neutron gets slower. Essentially, cross section is a measure of how big
the nucleus looks to the neutron.
QUESTION:
Have you heard of
"ball lightning?" If so, is it really lightning? Also, would you know of
the microwave ball lightning demonstration, and, if so, what degree of
danger it presents as an experiment?
ANSWER:
I have previously
answered this question. I don't know what the demonstration you refer to
is.
QUESTION:
Does the vapor generated by heating water in a
container increase if the volume of water is increased? That is, would 2
cups of water create more steam than 1 cup at the same heating
temperature? To me that seems logical, but someone told me that the rate
(water) vapor is generated might be limited by the surface area (the
same in both cases above).
ANSWER:
The rate at which steam comes
off is proportional to the net rate that heat flows into the water and
the surface of the water. So having two cups of water in a particular
pan on a particular burner does not generate steam at a greater rate
than one cup would. (Of course it will ultimately generate more steam.)
QUESTION:
My question is, does the electromagnetic field have a
dualistic property? Or is it better understood as a single entity?
ANSWER:
The most sophisticated way to think about it is as a single
entity. However, it is more comprehensible if we approach it from a
historical perspective (electric and magnetic fields). One reason this
approach is easier to understand is that the required mathematics are
less demanding: electric and magnetic fields are vectors but the
electromagnetic field is a tensor. Also, most devices fall rather neatly
into electric and magnetic categories.
QUESTION:
Is hinge a
simple machine?
ANSWER:
This is not something physicists really
worry about, more often it is important to fourth grade teachers
teaching science! It depends on how you define a simple machine. The
hinge itself would have a mechanical advantage of 1. The hinge-door
system might be considered a lever I guess.
QUESTION:
Have we
actualy measured the electromagnetic force of protons and electrons or
are there values simply theory?
ANSWER:
Yes, of course we have.
The measurements are amazingly accurate.
QUESTION:
I am a 5th
grader in Texas and I am working on a science project concerning
friction. Could you tell me how friction works?
ANSWER:
Friction is a very complicated thing microscopically and you should
probably not, at your age, try to dig too deep since this is not a
terribly well understood thing. I would recommend that you focus your
project on something like the empirical observation that the force of
friction when something slides is proportional to the normal force (the
force a horizontal surface exerts upward on the sliding object). This
normal force is just the the weight of the object and whatever is
stacked on top of it if the surface is horizontal. Therefore, suppose
you have a wooden block sliding on a wooden table top. If you measure a
frictional force of 1 lb if the block weighs a half pound, then if you
add another half pound to the block it should have twice the friction
force, 2 lb.. Note that the surface area of the block does not matter,
according to this empirical "law". I think it would be a good 5th grade
project to test this. I have judged many science fairs and have always
found that the best projects are those with a simple, well-focused,
interesting, and achievable objective.
QUESTION:
please explain
briefly: cold is merely the absence of heat and darkness is simply the
absence of light.
ANSWER:
Cold and dark are qualitative terms,
not quantitative. If on object is colder than another the energy per
molecule is smaller. Dark usually refers to absense of visible
electromagnetic radiation but also sometimes can refer to absense or low
intensity of other wavelengths. Dark also does not necessarily imply
absense but may imply low intensity; when we say it is dark out we
certainly do not mean there is absolutely no light.
QUESTION:
To
calculate the escape speed from the the earth's surface is
straightforward with KE = PE. How would I approach the same calculation
if a hole were drilled to the earth's center and I wanted to launch from
the earth's center?
ANSWER:
First you must make an assumption
regarding the earth's mass distribution. Although not true, most
standard problems of the type you present, assume a uniform mass
density. In that case you will find that the force on the object
increases linearly from zero at the center until you reach the surface.
Therefore, the problem is simply a simple harmonic oscillator problem
(identical to a mass on a spring). This is a standard problem you will
find in many elementary physics textbooks. So you must calculate the
speed the particle would need at the center of the earth to have the
usual escape velocity at the surface.
QUESTION:
Can an object
that is heated only get as hot as the flame that is heating it? I've
thought about this question for a while and intuitively it seems that an
object can only get as hot as the source. However, if we think of the
source as having an infinite source of energy that is supplying heat to
an object and that object can only dissipate heat at a certain rate due
to radation, convection, etc...then at some point couldn't the object
get hotter than the flame? At some point there will be equilibrium but
that doesn't limit the object to the flame's temperature correct?
ANSWER:
The flame is not just some object at some temperature, it
is a source of energy. An object in a flame can, as you correctly
conclude, become hotter than the flame itself since heat will
continually flow into the object from the flame and, if heat leaves more
slowly, will continue increasing its temperature.
QUESTION:
my
question concerns the hypothesized constant expansion of the universe.
if the universe is growing exponentially as predicted, would not every
object that we use as measurement also expand proportionally? thus it
would be entirely impossible to measure such expansion? also, in what
way does such an expansion change our view of the universe?
ANSWER:
It is the universe which is expanding, not the space in
which it is embedded (although that is changing also but differently).
Imagine two cars moving away from each other: would you measure, with a
meter stick on one of the cars, that they were not?
QUESTION:
When we drop water on tissue paper, why does it spread evenly ?
ANSWER:
Because of capillary action.
QUESTION:
If everyone
in the world began to walk due east at a given time, would the rotation
of the earth slow down (in order to conserve momentum)?
ANSWER:
Technically, yes (it is angular momentum conservation). However, the
mass of all the people on earth is so small compared to the total mass
of the earth that the effect would be too small to measure. (See
following question.)
QUESTION:
I wonder: in the event the north
pole (artico) thaw completely and turn around the ice water, the balance
of rotation of the earth suffer amendments? The masses of the planet
will have to be redistribuidas to enter new balance? The axis of
inclination of 23 degrees should be amended because of this?
ANSWER:
The total mass of all the water on earth compared to the
total mass of the earth is so small that the effect would be too small
to measure. (See preceding question.)
QUESTION:
I have question
regarding conventional radar systems. As you're aware, stealth
technology is based on the notion of reflecting, absorbing, scattering
radio signals and cancelling them at the source. Conventional radars
look for a positive image of the sky. Rather than looking for a positve
image of the sky, what if we look for a negative image instead. If we
used naturally occuring or systhesized background radiation, couldn't we
passively look for holes at ground sites? In other words, look for the
absence of radiation rather than it's presence. Track and triangulate on
holes rather than positive returns. Also, if our background radiation
source is broad, could we also determine molecular composition of a
target through the methods used in spectroscopy?
ANSWER:
In
principle you could do something like you suggest. But let me point out
a few difficulties:
Background radiation is relatively weak and
difficult to receive reliably.Background radiation is a whole spectrum
of wavelengths, some of which would go through, some of which would
diffract efficiently around the aircraft.Because it is a whole spectrum,
your detector would have scan frequencies or lock in on one you like,
which would further enormously reduce the intensity.The radiation comes
from all directions so you would need very tight directional detection,
again greatly reducing the already tiny intensity.Overall, it is not
practical.
QUESTION:
when you walk, do you do any work? The force
I believe is perpendicular to the motion (which means no work), but why
do you move forward?
ANSWER:
I have previously answered this
question.
QUESTION:
How long will carbon dioxide take to disperse
in a closed container because of the Brownian effect? How does the
Brownian effect work?
ANSWER:
Brownian motion refers to
particles suspended, not to other gases or liquids. The carbon dioxide
will diffuse into the rest of the gas. The rate of diffusion and the
time it takes depends on many things that you have not given information
about like temperature, volume, pressure, etc.
QUESTION:
according to Einstein's special theory of relativity the rate of time's
progression for any body is contingent upon its speed. Is it posssible
to express the rate of times's progression for a body without relating
it to other rates of progression (greater or less than another by some
factor)? is there some variable, indepedent of time, to which a rate
could be expressed with respect?
ANSWER:
In any frame of
reference, a clock runs at exactly the rate you would expect it to if
you are in that frame. All other clocks run slower than yours if not at
rest in your frame.
QUESTION:
There are two objects equal in mass
and size and shape... identical blocks of wood for example. They are on
a horizontal plane with no friction. The first object moves at 10 mph
and collides with the second which is at rest. The two masses merge
together (unlike billiard balls,where one stops and the other moves on),
and continue as one mass. How fast will the two be travelling after the
collision? It seems like it should be half of the speed of the original
object, but i was told by a physics instructor that it would be more
like 90 percent of the speed of the original object, allowing an
arbitrary 10 percent for heat loss in collision. But, doesnt the first
object give up some of its speed to the mass of the second object, so
that both now move with the same energy at a lower speed?
ANSWER:
Wow, either you misunderstood your instructor or else he has no business
being a physics instructor. What you describe is called a perfectly
inelastic collision but in any collision where there are no external
forces (the only relevant forces here are the forces the two blocks
exert on each other) the linear momentum must be conserved, that is
remain constant. The linear momentum is the mass times the velocity, and
it must be the same before and after the collision. Before the collision
the momentum is mv1 and afterwards it is mv2+mv2=2mv2. Therefore,
mv1=2mv2 or v2=v1/2, exactly like your intuition told you. What is not
conserved is the energy. Before the collision, E1=˝mv12 and after the
collision, E2=˝(2mv22)=Ľmv12. So, you see, exactly half the energy was
lost and most of this will show up as thermal energy.
QUESTION:
Has anyone measured the amount of time it takes for electrons to jump
from one atomic orbital to another? For example, how long does it take
for a stimulated electron in a hydrogen atom to jump from a 99%
probability of being in the 2s orbital to a 99% probability of being in
the 1s orbital? And, when during the transition does the quantum of
energy get emitted?
ANSWER:
You could not make this measurement
on a single atom without disturbing the system. The only way to do this
is statistically with a large ensemble atoms and the information you get
is the transition rate or half life.
QUESTION:
Since water is
incompressible, could a deep-diving "chamber" for an aquanaut be built
by means of a transparent balloon full of water in which the aquanaut
would float suspended without being subject to the pressure of whatever
depth the balloon assumed? This balloon would submerge, surface and
maneuver by means of machinery external to its surface, controlled
(perhaps) via fiber optics links.
ANSWER:
The pressure inside
the balloon would increase just like the water on the outside; just
because the volume remains constant does not mean the pressure does not
increase. Imagine a volume of water in a cylinder with a piston on top
and an aquanaut in the water. Now start piling weights on the piston;
the volume stays about the same (nothing is perfectly incompressible)
but the pressure will increase. Same idea.
QUESTION:
I am trying
to figure out a simple puzzle, which is in my head a bit confusing. The
puzzle is this: If I mount a cannon on the posterior surface of the
earth, that is the rear of the planet as it circles the sun, pointing
the camera perpendicular to the plane tangent to the surface, that is
apparently straight up as seen from an observer on the ground, and fire
the cannon, then the earth should see a tiny increase in speed equal to
the momentum of the cannonball divided by the mass of the earth. Then,
as gravity slows the cannonball eventually to a stop this increase in
speed should be cancelled by the cannonball's pull on the earth. I
suppose I am wrong but this seems to be a zero sum situation. Then as
the cannonball comes back down and slams into the earth, the original
momentum is once again returned to the earth, effectively once again
adding speed to the earth. In all of this there is an overall net gain
in speed imparted to the earth without any mass being ejected. Since
this makes no sense to me I would like to know where my conceptual error
lies.
ANSWER:
The cannon fires and momentum is conserved, that
is the momentum of the earth plus the cannonball are equal and opposite,
adding to zero. Note, however, that energy is not conserved because both
the earth and cannonball have kinetic energy; this energy came from the
chemistry in the gunpowder. During the whole flight of the cannonball
momentum is conserved so that the earth and the cannonball always have
equal and opposite momenta. So when they collide they are both moving,
the earth "upwards" and the cannonball "downwards". They now collide and
stick together; momentum is still conserved, so they must both end up at
rest because the total momentum must remain zero and both must have the
same speed which must be zero. Energy is not conserved since the kinetic
energy disappears; this energy shows up as thermal energy (ball and
earth heat up a little), energy of the sound produced, work it takes to
squish the earth, etc.
QUESTION:
I've read your answer about a
theoretical mirrored room and whether or not the room would remain lit
after turning off the light source. My wife has this crazy idea that due
to light pollution, even if all the lights in a city were turned off,
the glow of the lights would remain for some period of time. I've
explained that the if the bulbs were turned off, the existing photons of
light would be absorbed, reflected off into space, etc... nearly
instantaneously and the entire city would become dark. She insists that
the atmostphere would still have light bouncing around and would still
give off light. She says that this question won't be put to rest until
somebody with serious Physical knowledge gives a complete answer. Can
you tell me wife she's being silly and doesn't know what shes' talking
about?
ANSWER:
Certainly energy is conserved. However light is
usually absorbed and then reemitted as radiation which is outside the
visible spectrum. For example, the greenhouse effect is when visible
light is absorbed and reemitted in the infrared; the infrared does not
effectively penetrate out of the atmosphere so that energy is trapped.
But you cannot see it. I agree with you that visible light will almost
instantly dissappear when the source is extinguished. An exception would
be if you had phosphorescence, the phenomenon behind "glow-in-the-dark"
materials, but the air, clouds, and most of the world is not
phosphorescent.
QUESTION:
I've read about the wigner effect where
exposure to fast neutrons can store energy in graphite that can later be
released as heat. My question is, if graphite is exposed to neutrons in
a "clean" environment (not contaminated by other radioactive elements)
does exposing the graphite to neutrons make it radioactive too?
ANSWER:
This effect is an atomic, not nuclear phenomenon, where
atoms of carbon are displaced from their previous locations in the
crystal lattice. It is essentially what is called radiation damage and
results in such things as electronic components being ruined by exposure
to radiation. There is no radioactivity associated with it. That is not
to say that there is no radioactivity as a result of neutron activation
but I would bet that it would be vanishingly small because if carbon
absorbs a neutron (for which the probability is very small) it will
simply make another stable isotope of carbon. More exotic reactions
could occur but these would be rare. Neutron absorption by impurities in
the carbon could also occur, but you presumably would have a pretty pure
graphite sample.
QUESTION:
An elementary problem in Newtonian
physics is to show that the theory predicts simple harmonic motion of a
test object falling through the center of a uniformly dense spherical
mass. I've never seen, either in the context of this problem per se or
otherwise, any DIRECT empirical evidence in support of the Newtonian
prediction. Confidence in the solution appears to be entirely based on
observations of motions very far from the centers or beyond the surfaces
of gravitating bodies; i.e., extrapolations. It seems to me that the
oscillation -- or at least a first approximation thereof -- would not be
too difficult to arrange with a suitably modified Cavendish balance. Has
an experiment like this ever been tried? If not, why not?
ANSWER:
And the point of this experiment would be…? Gravity is one of the best
understood of nature's phenomena and there is really no need to verify
each cute little example which has been dreamed up. The idea of drilling
a hole all the way through the earth will obviously not work not to
mention that the earth is not really a uniform sphere. To do as you
suggest is really hard because the Eötvös experiment is one of the
hardest around to perform with precision (a group of renoun
experimentalists at the University of Washington has been working for
years to measure G with great precision this way). The main reason is
that gravity is so weak even for objects of mass of tens of thousands of
kilograms which you might be able to do an experiment with will
experience forces so weak that it might take years for one oscillation
to occur. Similar experiments are much easier with electric charges
which are also 1/r2 forces.
QUESTION:
In a home refrigerator
freezer set to 0 degrees F, assuming all the contents have enough space
to give up their heat, will all the contents eventually end up at 0
degrees F? I'm aware that not everything freezes (which I read as
"becomes solid") at 0 degree F, so some of the freezer contents could
still be liquid or flexible (as in sports gel paks). If not all the
contents go below 0 degree F, why not? And at the other end of the
thermometer, why can I pick up aluminum-wrapped bread just out of the
oven with my bare hand? Is the aluminum not as hot as the oven? If not,
why not? Thank you very much.
ANSWER:
In an isolated system,
which we assume the inside of the freezer approximates, everything will
eventually come to thermal equilibrium, that is everything will
eventually have the same temperature. Your other question, about the
foil, I answered a long time ago.
QUESTION:
I am struggling to
understand why it is easy to balance a basketball on your finger when it
spins but difficult when it is not spinning. I consider the motion of
the center of the ball, since it moves as though all its mass is
concentrated there and all external forces are applied there. When the
spinning ball tilts slightly so it its axis is at a slight angle from
vertical, gravity applies force at the center of mass to pull it off
your finger. There must be a countering torque when the ball is spinning
to balance the ball on your finger and keep it from falling. Due to the
torque from gravity, the ball precesses so its center of mass moves in a
circle around your finger. Since the center of mass moves in a circle,
there must be a net centripetal force greater than zero acting on the
center of mass of the ball. I believe this centripital force provides
the countering torque to balance the ball. If the ball was not spinning
there would be no countering torque because the center of mass would not
move in this circle. The problem I have is that I know that the precess
angular velocity (which to my understanding is the angular velocity of
the center of mass of the ball as it moves in this circle) is inversely
related to the angular velocity of the ball. So the faster the ball
spins, the lower the precess angular velocity when it tilts at any
angle, and therefore the lower centripetal force and lower countering
torque. This seems backwards to me because it seems that there should be
more countering torque when the ball spins faster.
ANSWER:
The
spinning ball has an angular momentum which is a vector which points
along the rotation axis. I will suppose that this vector points
vertically up (which means that the spin is counterclockwise as seen
from above}. The nonspinning ball has no angular momentum. Now, if the
ball starts to fall toward the left as seen by you there will be a
torque about your finger which points toward you. Newton's second law
states that torque is equal to the time rate of change of the angular
momentum, so if the ball is initially not spinning it has no angular
momentum so after a short time it has a small angular momentum toward
you which means that it is falling to the left; but the torque gets
bigger as it falls further so the falling accelerates. Now, if the ball
starts with an angular momentum it will be changed also by a small
amount toward you but since it already had a lot, its angular momentum
vector will change its direction slightly toward you in a short time;
this is precession. So, you see that a small error in balance leads to
falling for the nonspinning ball but precession for the spinning ball.
Now, you simply keep correcting as precession starts which is easier to
correct than if falling starts.
QUESTION:
I have some questions
regarding strength of an electromagnet
1) Does the size and the
material of the core affect the strength of an electromagnet?
2)
Does the thickness of the coil affect the strength?
3) The
electromagnets I've seen so far had only one layer of coils wrapped
around them. Would the electromagnets become stronger if I warp a
multiple layer of coils around them?
ANSWER:
The field is
proportional to the current around the core and the number of turns per
unit length. Therefore the strength is not greater but there is more of
it over a larger area. However, the material certainly matters and a
ferromagnetic material, usually iron, works best.Answer 1 covers
this.Again, answer 1 covers this because if you wrap two layers around
you are essentially doubling the current.
QUESTION:
What causes
gravity? How can gravity be explained? General Relativity, as I
understand it, says that gravity is not a force or interaction. Rather
that spacetime is "curved" by the presence of mass, and that this curve
"tells" other matter ( a test mass?) how to behave. Have I got that
right? But the question remains does it not? Accepting what GR says is
one thing, but in reality the real question is why or how does mass
cause spacetime curvature? Am I thinking correctly here? I teach
astronomy at a local school, and some of those kids come up with some
tough (for me) questions.
ANSWER:
General relativity starts with
a simple premise, the equivalence principle: there is no experiment you
can perform which can distinguish whether you are in a gravitational
field or in an accelerating frame of reference. For example, if you were
in an elevator which was accelerating and a beam of light entered
through the side it would follow a curved trajectory to the opposite
wall; this is exactly what would happen if you were sitting still in a
gravitational field. This principle, coupled with the principle of
special relativity (the laws of physics are the same in any inertial
frame of reference) leads to the general principle of relativity, the
laws of physics are the same in any frame of reference. One implication
of this theory is that mass deforms spacetime which is, as you state,
how gravity works; mass deforming spacetime is simply a consequence of
the postulates of the theory. Is it the last word? Probably not because
gravity has not been reconciled with quantum theory and the quest for a
theory of quantum gravity is one of the holy grails of physics. I would
not say that gravity is not a force just because we understand the
mechanism for that force. Asking "why or how" mass causes the curvature
is essentially equivalent to asking what is mass, why do objects possess
it? The current well-publicized quest for the Higgs boson is important
because this is the particle which physicists think is responsible for
endowing the elementary particles of nature with mass.
QUESTION:
Are metals more efficient as thermocouples or alloys?
ANSWER:
What does efficient mean in this context? Most sensitive? All common
types of thermocouples have one or both metals being alloys.
QUESTION:
Two friends are standing on opposite ends of a canoe. The
canoe is initially at rest with respect to the lake. The person on the
right throws a very massive ball to the left, and the person on the left
catches it. After the ball is caught, the canoe is (ignore friction
between the canoe and the water) moving in what direction? A.) To the
left. B.) To the right. C.) Stationary
ANSWER:
The linear
momentum must be conserved because there are no external forces on the
system (boat, ball, and two people). Since it starts out at rest it ends
up at rest. During the time the ball is in flight the canoe and
passengers must move in the opposite direction, so they do not end up in
the same place, but still at rest.
QUESTION:
Can energy exist
only in certain quantities, or can it exist at any level, but only be
realesed at fixed amounts, or neither? If so what is the minimum amount
of energy possible?
ANSWER:
For a given system, e.g. an isolated
atom, a mass on a spring (harmonic oscillator), or a beam of light of a
given frequency, the energy may only have certain discretized values.
The simplest example, the photon, of which the light of frequency f is
composed, must have an energy of only hf where h is Planck's constant.
Therefore the energy of a beam of that light may only have a total
energy of some integer times hf. However, there is no constraint on what
the frequency can be and so there is no constraint which says that the
energy of a beam of light must be discretized. Similarly, the energies
of a harmonic oscilator of a particular mass on a particular spring are
quantized; however, there is no constraint on the value which the spring
constant can have, so energy itself is not constrained to only discrete
values.
QUESTION:
I have a problem with making a contraconcave
mirror. Please refer to these links if my question is somewhat
incomprehensible...I seem to be having a hard time wording this
question...
http://ec.hku.hk/schoolscience/Volumes/Vol_3/SSHK_Vol_3_03.pdf
http://www.wfu.edu/physics/demolabs/demos/6/6a/6A2035.html
http://www.i-am-bored.com/bored_link.cfm?link_id=17162
Anyways, it
seems fairly simple enough to make this, however, I am facing two major
problems. These are:
1. How can one find out the focal length of any
given concave mirror? Is there a formula defined for this?
2. How
would the size of the hole in the top mirror affect the mirage produced?
If the hole has to be of some exact size, how can one find out what size
should it be when making a contraconcave mirror?
ANSWER:
If it
were a spherical mirror, the focal point would be half the radius of
curvature of the mirror. In the case of a parabolic mirror, the focus is
at the focus of the paraboloid. However, It is realatively easy to
directly measure the focal length by focusing a distant object (the sun
is good) to a point; be careful, though, since the focused sunlight can
burn what it is focused on. The hole does not effect the quality of the
image because the mirror uses all points on its surface to form the
image. Cutting a hole anywhere will slightly reduce the brightness of
the image, not its quality.
QUESTION:
I work in an industrial
plant and we have air diffusers which are round and have small holes
punched in them in a regular pattern. So think of it as a tube about 2
feet in diameter standing on end. The small holes (.125 inch or so) are
regularly spaced about .375 inch or so apart. When you stand back from
the diffuser you see a pattern that changes depending on your
orientation to the diffuser, you see a pattern of much larger light and
dark areas that seem to match the pattern of holes in the diffuser
(tube) the patterm remains the same, but the size of the pattern will
change with distance from the object. I've also seen this same effect
when I lay one material with a pattern on top of identical piece of
material with the same pattern that is back lit, as you change the
orientation relative to each other you see the pattern seem to shift and
expand in size. Is this just a complicated version of the interference
pattern from the famous 2 slit experiment that proves that light has the
properties of both a wave and a particle?
ANSWER:
I believe what
you are seeing is a moiré pattern which is what you see when you
superimpose two or more patterns on top of each other. It is a type of
interference on a macroscopic scale, that is, it is not the light which
is interfering but the patterns themselves. An example is shown at the
right. The fabric satin is pretty because of this kind of effect. You
can download some software where you can play around making your own
moiré patterns. I guess that I am a little surprised that you can
actually see this in this circumstance since I would expect that you
would not be able to see the air from the holes as being distinct from
the ambient air; maybe it is a different temperature, or contains a
little dust, or…? Have you tried to photograph it? I would be
interested.
QUESTION:
I teach 5th grade science, and I
desperately need a fifth grade answer to this question. I have wonderful
bright students who ask excellent questions and I stuggle to answer
accurately without completely overwhelming them. "If light is
electromagnetic waves caused by the vibrations of atoms or electrons,
and if a vacuum is defined as the absence of all matter; then how can
light travel in a vacuum?"
ANSWER:
Imagine two magnets in a
vacuum. Do they exert forces on each other? The answer is yes as you
could prove in your classroom if you have a bell jar to create a vacuum
in. What about electric forces? Think about an atom: the nucleus exerts
a force on the electrons even though there is a vacuum between the
nucleus and electrons. So, both electric and magnetic forces can be
transmitted through a vacuum. Physicists often express the presence of
forces experienced at some point in space by the existence of something
we call a field. If a magnet feels a force it is because it is in a
magnetic field; if an electric charge experiences a force, it is because
it is in an electric field. Hence, fields can exist in a vacuum. An
electromagnetic (EM) wave (like light, radio waves, microwaves, x-rays,
etc.) is composed of electric and magnetic fields which are oscillating
and move through space with a speed of 186,000 miles/second. A picture
of an EM wave is shown above. Think of this as a snapshot; a little
later the whole thing will have moved to the right. This is why EM waves
have no trouble propogating through a vacuum.
Extra material for the
teacher if you think the kids can get it:
If there are fields in a
wave, then where are the charges and magnets which cause fields? It
turns out that if a magnetic field changes it can cause an electric
field (which is how generators work) and if an electric field changes it
can cause a magnetic field (which is how electromagnets work).
Therefore, if you get a wave going (from an atom or from an antenna), it
will keep itself going as it propogates.
QUESTION:
On a sunny day
when a sun angle shadow can be measured, and knowing the time of day,
how would you calculate the latitude for that position? Also, it you
note the sun angle rate of change, dy/dt, can you also determine the
longitude by angular displacement or by linear translational velocity?
Lastly, if you look at a day/night view of the Earth, the curve appears
sinusoidal with respect to the equator. If that's true, then all sun
angles on the sunny side should also follow a similar curve. That being
said, how would you calculate the longitude/latitude fix of a given sun
angle with respect to some other know point along the sinusoidal path?
ANSWER:
In principle, it is simple, just a problem in
three-dimensional geometry; you need to know the two angles which
specify where the sun is in the sky, the angle of tilt of the earth's
axis, and the exact time of year. In practice it is a very complicated
process. Nowadays, you could program a computer to take the input data
and output the latitude, but I have never heard of this being done since
GPS systems make it all so simple. In traditional celestial navigation
you wait until the sun is at its highest point, measure the angle, and
look up your latitude in a table which is appropriate for the date. Of
course, the tables would be in a laptop these days. I do not understand
your second question at all. Your third question, the "sinusoidal"
day/night boundary, refers to an illusion; the boundary on the globe is
a simple circle around the earth and that which you see on a flat map is
an artifact of the projection from the sphere.
QUESTION:
An
object in motion has kinetic energy. Energy/mass warps spacetime. So as
you accelerate, let's say an electron, arbitrarily close to the speed of
light (hence its mass/energy increases without bound) ... at what point
does its kinetic energy cause gravitational collapse into a blackhole?
And couldn't two observers in relative motion each argue with equal
validity that its an electron (with respect to its rest frame) or a
blackhole (at 99.999 ... 999% c)? Would this imply that were I to chase
after and catch up to the electron so that it is now at rest in my
reference frame, it somehow undoes its own blackhole formation before my
very own relativistic eyes?
ANSWER:
As I have said many times in
previous answers I consider the interpretation of special relativity
that mass increases with speed to be a good qualitative crutch at best.
Your question is one of the best arguments I can think of to support
this point of view. Although there are lots of other reasons to consider
an electron as an impossible candidate for a black hole, how could it
both be and not be one? In its own rest frame the electron would not be
a black hole.
QUESTION:
The whole of an electron is negatively
charged, what stops the particle blowing itself apart?
ANSWER:
Let's look at something else as an example to put my answer in context.
Why does a nucleus, positively charged, not blow itself apart. Because
the strong nuclear force, which is attractive for protons/neutrons
interacting with protons/neutrons, holds it together. Why does one of
the constituent protons not blow itself apart, being positively charged?
Because it is composed of fractionally charged quarks which interact
with each other via gluons (which is ultimately, the origin of the
strong nuclear force. Then why do not the charged quarks blow themselves
apart? Because we regard them as fundamental, elementary particles which
simply are as they are. I know, that is a very unsatisfying answer, but
eventually in science you get down to a point where, until something
better comes along, it is simply the best answer. An electron, like a
quark, is believed to be a fundamental particle, and is simply
indivisible.
QUESTION:
Gravity question. If a bowling ball and a
tennis ball are dropped from the same spot they will hit the ground at
the same time. So why do I (bowling ball) get to the bottom of a snow
covered hill so much faster than my daughter (tennis ball)? We are
falling aren't we? Aren't the factors of friction (weight and sliding)
balancing with each other?
ANSWER:
This is not an easy question.
See my two previous answers.
QUESTION:
Is it possible to describe
the motion of a double pendulum as a function of time alone? If so what
would this function look like?
ANSWER:
Well, sure but not in
terms of mathematical functions you would be familiar with. Even the
simple pendulum is easily solvable only for small oscillations. The most
useful analytic solutions to such problems involve what are called
normal modes; choosing the initial conditions then determines a
superposition of these modes. However, the most useful solutions are
often computer simulations which are numerical computations of the
function which interests you; this is particularly true for large
amplitudes of the double pendulum which are chaotic.
QUESTION:
I
was curious, if you plugged in the Rydberg Constant, into einstein's
equation e=mc2, could you get the smallest theoritical mass of a
particle?
ANSWER:
Where would you plug it? The Rydberg constant
has the dimensions of 1/length, SI units of m-1, so it is neither an
energy nor a mass. Also, why would you think that there were some
generalization here when the quantity is specific to the hydrogen atom?
You are also ripe for a physicist's reprimand: physics is not about
QUESTION:
I was wondering about light falling into a black hole. If
gravity is pulling light in doest this imply that gravity can accelerate
things beyond the speed of light? Or that the force of acceleration of
gravity is faster than the speed of light? Have velocity calculations of
the x rays and other high energy states leaving black holes? If one were
to shine a light beam and an x ray out of a black hole and the light
falls bends back in while the x ray escapes, wouldn't this mean that the
x ray is technically moving faster than light in that specific state?
ANSWER:
When light is acted on by gravity it does not accelerate
like matter does but it does have its energy changed. Light falling into
a black hole gains energy so its wavelength gets shorter. But all
electromagnetic radiation moves with the same speed in vacuum. And
x-rays are no different in this respect. No radiation, regardless of
energy, can escape a black hole. And no electromagnetiic wave in a
vacuum moves with a speed other than 3 x 108 m/s.
QUESTION:
Lets
imagine i have a long stick(please continue reading) thats rounded and
as long as the galaxy itself, im holding one side of the stick and the
other side is near me, but the stick is a big halo that outlines the
galaxy, my question is, if i move the side im holding how long will it
take the "move" to reach the other side of the stick, lets say i give 1
step with my stick, how long will it pass until i see the other end
moving. I was wondering if that would be faster than the speed of light.
I'm here at earth with a stick as long as 4 years light, can i poke
instantly somebody by moving this imaginary stick. For the purposes of
this the stick wont brake and its light.
ANSWER:
The
implications of your question emphasize that it is really unphysical.
Suppose we make the halo as light as possible: I reckon that the number
of atoms if the halo is a single chain of atoms would be about 1031 and
the mass would be on the order of 1,000,000 kg. And this would not be
very strong would it? Anyhow, the motion at the other side cannot happen
faster than the speed of light and it would not even come close to the
the speed of light, more like the speed of sound in the halo. I have
previously answered a similar question.
QUESTION:
Is there any
tangible evidence to Planet X and 2012? If so, why isn't EVERYONE
talking about this now? If this thing actually enters our solar system,
then we're all history. Is that correct?
ANSWER:
The first
thing that comes up on a google search is a site devoted to Nostradamus
prophesies. Does this tell you anything about tangible evidence?
QUESTION:
if one were to stand on an infinitely large plane and look
off into the distance there would be a horizon. how would one calculate
the apparent vertical distance between the lowest point visible and the
horizon? As an object moves away from a viewer its apparent size becomes
smaller and smaller. If an object were to move away from a viewer at
constant velocity what function would designate its apparent size with
respect to time?
ANSWER:
A horizon is the line beyond which you
cannot see the surface. There is no horizon on an infinitely large
plane. An object moving away at constant rate would shrink in apparent
size at a constant rate.
QUESTION:
I'm studying Specific Latent
Heat at the moment, and I've taken an interest in Plasma outside of
school. So I came up with a question, that my teacher couldn't answer.
Is there such thing as a Specific Latent Heat Of Plasmarisation? Or
something along those lines?
ANSWER:
It takes a certain minimum
amount of energy to ionize an atom. You could therefore define some sort
of specific heat but I have never heard of anybody doing it. One reason
not to do it is that atoms (except hydrogen) can become multiply ionized
so that some of the energy you put in would be used to remove even more
electrons from already ionized ions rather than to atoms not yet
ionized. Melting ice, on the other hand, you use all energy of your
latent specific heat to melt, you can't melt it further.
QUESTION:
I have a cylinder which has a piston inside it, 2 inches in diameter.
When the end of the cylinder is unrestricted, (a 2 inch opening) it is
very easy to draw material into the cylinder and to expell it from the
cylinder by moving the pison back and forth. But if the opening of the
cylinder is restricted down to 1/2 in diameter, it becomes much harder
to draw material in and out of the cylinder. What is the physics behind
this?
ANSWER:
Bernoulli's equation is ˝ρv2+ρgh+P=constant. Here
ρ is the density of the fluid, h the height above some reference, and P
the pressure. In this case h is about the same for fluid inside and
outside the piston. The pressure outside is atmospheric regardless of
what happens inside, so the constant is the same regardless of which
opening you use. The half inch opening has an area 16 times smaller than
the 2 inch opening, so the velocity will be 16 times greater for the
same rate of flow. Therefore ˝ρv2+P2"=˝ρ(16v)2+P˝". So P˝"=P2"-˝(255)ρv2
so the pressure for the smaller opening must be much lower to move the
fluid at the same rate which means you have to pull on the piston much
harder. This analysis neglects things like viscosity, compressibility,
etc. but gives a reasonable qualitative explanation.
QUESTION:
I
have a question relating to an aircraft in flight. Since the total
mechanical energy of an aircraft in flight is the sum of it's potential
energy and kinetic energy, is the total mechanical energy of the
aircraft derived from the fuel source? In other words, does the BTU
equivalent of the energy expended by the power plant equate to the total
energy of the aircraft? If not, where does the additional energy come
from?
ANSWER:
Suppose you suddenly acquired a tailwind. The
kinetic energy of your airplane would increase without any additional
expenditure of fuel. Also, nearly all the fuel you consume is not used
to give energy to the aircraft but rather to make up for the energy lost
to air resistance.
QUESTION:
Is there any definitive proof that
the rate of radioactive decay of any isotope is constant over the period
of Earth's existance?
ANSWER:
The halflife of any particular
radioactive nucleus is determined only by the constants of nature. There
is absolutely no evidence that there has been any change in the
constants of nature over so short a time as the age of the earth.
QUESTION:
Is gravity a form of energy?
ANSWER:
To create
energy you need to do work and to do work you need to exert a force over
a distance. Gravity is a force so it can do work. For example, drop a
ball and it acquires kinetic energy as it falls because of gravity.
QUESTION:
If I have a reservoir filled with water that's 10m deep,
10m long, and 10m wide. And if I have a square hole on the bottom of the
reservoir that is 2mx2m in size. And this square hole extends downwards
1m and runs under the reservoir 5m then up vertically 10m to exceed the
surface of the reservoir (10m+). What is the initial velocity of the
water at the start of the square hole (at -10m)? Also, will the water
reach the top (10m+)?
ANSWER:
I make the following assumptions:
the fluid is ideal, i.e. laminar flow, incompressible, no viscosity.
Then the operative equation is Bernoulli's equation,
˝ρv2+ρgh+P=constant. Here, the pressure P is the same at both the
surface of the reservoir and the surface in the tube so we may use
˝v2+gh=constant; I will choose g to be about 10 m/s2 to simplify my
arithmetic. Choose h=0 at the bottom of the tank and note that the
velocity in the 2 m2 tube is 25 times the velocity of the surface of the
reservoir. Then ˝v2+10 x 10=˝(25v)2 and so the speed v at the surface of
the reservoir is v=0.566 m/s and the speed at the hole is 14.2 m/s. Now,
for your second question, we are interested in what the heights of the
two surfaces are when the velocities of the surfaces are zero. From the
equation ˝v2+gh=constant you can see that when the velocities are zero
the heights must be equal. The relative heights of the surfaces will
depend on the details of the shape of the tube below the reservoir (your
descriptions are a bit ambiguous). I estimate that the volume below the
bottom of the reservoir is about 31 m3 and so 100h+31+4h=1000, so h=9.32
m. So the fluid will never rise even to the top of the reservoir.
QUESTION:
If you have two tires on a vehicle and they are the same
size and ambient temp, is it possible with the front tired at 0psi and
the back tire at 35psi to achieve 20psi in the front and 20psi in the
rear if you use the 35psi tire to fill the front 0psi tire?
ANSWER:
Provided that the volumes start the same and do not change the final
pressure in each will be 17.5 psi.
QUESTION:
I found that the
photon have zero rest mass, but when we apply the formula E=m*cc if the
rest mass is zero then the E=0. Is there another formula to calculate
the energy of a photon?. or E=mc*c only applies to macroscopic objects?
ANSWER:
E=mc2 applies only to a particle of mass m at rest; a
photon has no mass and is never at rest. The general relation is
E=√[m2c4+p2c2] where p is the momentum. (See an earlier answer for the
definition of relativistic momentum.) So a massless particle has energy
E=pc. The energy of a photon is also related to the frequency f of the
corresponding electromagnetic wave by E=hf where h is Planck's constant.
QUESTION:
In a vacuum photons travel at it's maximum speed. Then why
if they travel that fast based on the formula E=mc*c, why photons don't
convert into mass themselves?
ANSWER:
A photon is a stable
particle and will not change its identity spontaneously. However, you
can induce a photon to create mass. The most common process is called
pair production; here a photon, when passing close to a nucleus, will
spontaneously turn into an electron and a positron if the photon has
more than twice the electron rest mass energy. A positron is the
antiparticle of the electron and has the same mass and opposite charge.
(See the preceding question for discussion of energy of a photon.)
QUESTION:
;
I can not understand how Heisenberg principle is valid in
this case: an EM wave of wavelength L is faling from direction z on a
slit d. The photons have p(z)=h/L. So after the slit maximum p(x) = p(y)
as it was before the slit. So uncertainty in p(x) is limited to Dp=
p(y)-0=h/L. But the slit d can be made as small as desired thus making
Dp.d less then h (sufficient is d<L). What is wrong here? Or photons
just can't go thru apertures smaller than heir wavelength?
Thank you
very much. I am sorry you didnt understand the question and the fault is
mine. I really commited an error in writing p(x) = p(y) instead
p(x)=p(z). PLEASE TAKE A LOOK AT THIS. I simply mean there is not enough
p in the incident beam to satisfy HUP in the case when its wavelength is
smaller than the slit. (If the photons dont take impluse from the
walls.) Indeed the photons spray after the slit and according HUP
[p(x).d>hbar] the component of the impulse parallel to the slit p(x) of
at least one photon must be greater than hbar/d. But the photons which
are falling have p=hbar/L (L>d wavelength bigger than the slit). What
they can do after the slit is to turn to 90 degrees PI/2 maximum. If a
photon does so it would have maximum p(x) =p(z)=p=hbar/L Because the
impulse must be preserved p(x) can not be greater than p what it had in
z direction before the slit (e.g p=hbar/L). But this is smaller than
p(x)=hbar/D because L>D.
ANSWER:
The problem is that you are
treating a two-dimensional problem as a one-dimensional problem. A
vector may be uncertain with respect to either its magnitude or its
direction but in one dimension only the magnitude can vary. In the case
you describe, the narrower the slit becomes the more uncertain the
direction of the photon becomes because of uncertainty in the magnitude
of the x-component of the momentum. However, there is still the
constraint that the total momentum be unchanged, so the maximum value of
px is p when the angle with the z-axis is 900. As the slit approaches
zero width, the direction of the momentum becomes completely uncertain
as required by the uncertainty principle.
QUESTION:
Does a body
in the universe at the farthest distance away from the earth exert any
real or even theoretical gravitaional or other attractive effect on the
earth and vice versa?
ANSWER:
Such force would be so small as to
be unmeasurable
FOLLOWUP
QUESTION:
Is that the same as
non-existent or is it like thediference between .999 repeating and 1.0?
ANSWER:
Theoretically, the force is inversely proportional to the
square of the distance, so the force is not zero because the distance is
not infinite. However, with distances so vast, we can't really verify
this theory by a measurement because of the smallness of the force.
Another way to say this is that the laws of gravitation have never been
really tested for such huge distances. No good scientist would insist on
the correctness of a theory which cannot be tested.
QUESTION:
Compared to the buoyant force of the atmosphere on a 1-liter
helium-filled balloon, the buoyant force of the atmosphere on a nearby
1-liter solid iron block is considerally more, considerally less, or the
same. My classmante thinks its more because the baloon would displace
more space, but i thought it was the same because of the buoyant force
law?
ANSWER:
The buoyant force is determined only by the
displaced air and a liter of iron displaces the same amount of air as a
liter baloon, so both have the same buoyant force on them. But, the iron
has much weight greater than the buoyant force so it drops; the baloon
has has weight less than the buoyant force so it rises.
QUESTION:
A ship anchored at sea is rocked by waves whose crests are 14 m apart.
The waves travel at 7 m/s. How often do the wave crests reach the ship?
Using the formula speed=wavelength x frequency the answer would be .5
seconds. Conceptually it seems the answer should be 2 seconds. Can you
help explain?
ANSWER:
This sounds like homework, but you seem
to already have done the work; plus, you have commendably done one of
the most important things in solving a problem which is to ask yourself
"does this answer make sense?" You are confusing frequency and period.
Frequency is the number of crests per second, and 0.5 s-1 is the right
answer; check your answer for units, though, which should be inverse
seconds, not seconds. Period is number of seconds per crest, and 2 s is
the right answer. The period is the reciprocal of the frequency, T=1/f.
QUESTION:
Does background microwave radiation or the higgs field
provide a means of averaging the energy measured coming from different
directions and establish a "special reference frame" that is "at rest"
with the background of space?
ANSWER:
First of all, the Higgs
field is a hypothesis and never observed, so let's dispense with that.
The microwave background would appear to present us with a preferred
reference frame and, in fact, it does. However, this is not a violation
of the principle of relativity which demands that the laws of physics
are the same in all inertial frames: the laws of physics are unchanged
in a frame in which the average velocity of the background photons is
zero. You could also argue that a preferred frame is one in which the
average background photon has a velocity of 20 mi/hr toward the North
Star. All the background does is provide a particular inertial frame.
QUESTION:
Why is the speed of light, seemingly arbitrarily limited
to 299,792,458 meters per second? More exactly, in being a finite speed,
is there anything particular about a photon that makes it travel at this
speed in a vacuum, and not another speed, faster or slower? It just
strikes me as odd that this has never been explained to me before. I
understand that it simply an observation, but is it explained?
ANSWER:
There is absolutely no mystery why the speed of light is a
universal constant. Electromagnetic theory predicts waves with a speed
determined only by the strengths of the electric and magnetic fields in
empty space. An earlier question spells this out in detail. The fact
that Maxwell's equations (laws of electricity and magnetism) predict
this and Einstein felt strongly that the laws of physics should be the
same in all inertial frames is partly what led him to propose the theory
of special relativity. Incidentally, the speed of light is exactly the
number you quote because the meter is defined as the distance which
light in a vacuum travels in 1/299,792,458 seconds.
QUESTION:
If
a projectile is shot at high speed from a non-rifled barrel, from the
air into the water at an angle, what path does the bullet take through
the water? Does any projectile experience a "refraction-like" bending in
the water the way a light ray would when moving into an optically denser
medium? This question arose when a friend and I were discussing the
refraction of light from the perspective of individual photons. I guess
the bigger question is: can a strictly particle-view of light explain
refraction?
ANSWER:
If you do experiments with particles, you
get the wrong result for refraction, that is if the particle slows down
it is deflected away from, not toward, the normal to the boundary. So,
presumably your bullet would be deflected so as to move more parallel to
the surface. If too large an angle of incidence is used, the bullet will
skip off the surface, "total internal reflection" except it is really
what we would call external reflection in optics. Also, a stream of
particles doesn't partly reflect and partly refract, it is either one or
the other. Nevertheless, you can still get the right answer if, for
photons, you impose the principle of least time: the path taken by the
particle (photon) will be that which minimizes the time of flight.
QUESTION:
To my understanding no object can exceed can exceed or
even acheive a velo. If an object starting from rest were to have a
force exterted on it which would cause it to exhibit an acceleration of
30 km/s*s, according to kinematics after 2.7 hours the object should be
traveling at light speed. what would actually happen at this point? does
the inertia of the object become infinitely great? continuing to exert a
force on this object could cause no change in acceleration. for the
action of exterting a force on this object there could be no equal and
opposite reaction. does this not violate newton's first law? does this
not also violate the law of conservation of energy? If the force
exterted on the object over a distance (energy) doesn't go into the
acceleration of the object, where does it go?
ANSWER:
(Your
first sentence is a little difficult to read; I assume you are referring
to the velocity of light.) You cannot use classical kinematics to do
this problem because it is incorrect for high speeds. Instead of writing
F=m[dv/dt] you must write F=dp/dt where the momentum is defined as
p=mv/√[1-(v2/c2)] (not p=mv) where c is the speed of light. If you now
exert a force of 3x104 N as you propose (for a 1 kg object), the time to
reach speed v is given by t=v/√[1-(v2/c2)]/3x104. So, for example, to
reach speed c/2, half the speed of light, it would take, by my
calculation, about five and a half years. It would take infinite time to
reach the speed of light. When the speed of the particle is large,
adding energy by doing work increases the energy of the particle but it
changes the speed by almost nothing. (I have always thought that high
energy particle accelerators should be called energizers, not
accelerators!) You might find the answer to an earlier question
interesting regarding why momentum has to be redefined in relativistic
mechanics.
QUESTION:
Inertia is a property of mass but is it
necc. when moving a mass from rest to apply force or energy exclusively
to overcome inertia? In other words, when I begin pushing on a boulder,
regardless of friction, won't it remain temporarily motionless in spite
of my effort until I overcome the interia? Can that energy be
calculated?
ANSWER:
Any force you exert on the boulder will
cause the boulder to accelerate unless other forces on it prevent that.
You use the phrase "regardless of friction". Do you mean there is no
friction? If there is no friction, then that boulder begins accelerating
the instant you begin pushing on it; if the mass is very large and your
force is modest, the acceleration may be small enough for you to think
that it is not accelerating, but it is. However, friction here on earth
is never really zero. Here is what happens when you push on the boulder
(on level ground):
There is no friction before you begin to push, but
when you start to push a little the (static) friction turns on, the net
force is zero and there is no acceleration.As you push harder, so does
the friction, so still no accereration.If you aren't strong enough, you
will never be able to move it; for example, maybe the boulder is Mount
Everest which you will never be able to budge.But there is a limit to
how big friction can get, and if you are strong enough or the floor is
slippery enough eventually it will accelerate since you will now be
pushing with a force bigger than the frictional force which is trying to
slow it down.If you stop pushing, the frictional force will cause an
acceleration opposite the motion and it will slow down and stop.When it
stops, friction dissappears again.If the boulder does not move you
expend zero energy. If it does, the work you do on the boulder (your
force times the distance you push) is equal to the energy expended.
Don't forget that friction does work too, negative work since it takes
energy away from the boulder.
QUESTION:
WHAT MAKES SCIENTISTS
THINK THAT THE FUNDAMENTAL PARTICLES ARE ROUND SHAPED. AS THE STANDAR
MODEL SHOW IN ITS GRAPHIC?. WHAT SHAPE DO THEY REALLY HAVE?
ANSWER:
Just because a graphic shows something does not mean it should be taken
literally. Now, what do you mean by shape? Shape of the mass
distribution? the charge distribution? the current distribution?
Physicists measure things called moments which are used to quantify
shapes. For example, an electric dipole moment of a neutral particle
would imply that there was some positive charge on one side of the
particle and an equal amount of negative charge on the other. An
electric quadrupole moment of a charged particle would imply a
football-shaped (positive moment) or doorknob-shaped (negative moment)
charge distribution. The earth is known to have a large monopole moment
(it's mainly a sphere), a modest negative quadrupole moment (bulges at
the equator), and a small octupole moment (somewhat pear-shaped).
Extensive measurements of moments have been made for nuclei but little
is known about elementary particles. We really have no means of
measuring mass moments which is probably what you think about when you
think about the shape of something. It is often assumed, at least for
nuclei, that mass distribution usually follows pretty closely the charge
distribution.
QUESTION:
Assume that our sun is not a large
gaseous sphere but a solid of the same mass. It will attract and hold an
atmosphere. What would be the density of the pseudo solar atmosphere at
the surface and how thick would such an atmosphere be? Also, considering
the refractive index of air on earth, how would the refractive index on
this pseudo solar atmosphere vary with altitude?
ANSWER:
This
is a pretty complicated question and the answer depends on what
assumptions you make in modeling the atmosphere. I will assume that the
density of the atmosphere is independent of temperature and that the
areal density (the mass above a given area of the "planet") is the same
as for the earth. You say that it "will attract and hold an atmosphere".
Hold an atmosphere, yes, but it wouldn't attract an atmosphere since
space is essentially empty so whatever it has would have to have already
been there or to get there somehow. It is fairly easy to show, given the
mass of the sun and its radius, that the acceleration due to gravity at
the surface would be about gS=270 m/s2 compared to the earth's
approximate gE=10 m/s2, about 27 times bigger. If we assume the density
ρ of the compressible atmosphere is proportional to the pressure P,
ρ=ρ0P/P0 where P0 and ρ0 are the pressure and density respectively at
the surface of the planet, we find that pressure as a function of height
h is P=P0exp[(-gρ0/P0)h]. Because the areal mass density is the same as
on earth, one may now show that the pressure and density at the surface
are about 27 times greater than on earth. Similarly, the height at which
the density would drop to some fraction of what it is on the surface
would be 27 times smaller than on earth. The question regarding index of
refraction is too technical for this site and depends on assumptions;
clearly, the index would be larger than for earth's for my model because
the gas is much more dense.
QUESTION:
Consider this scenario -
there's a room full of mirrors (for argument's sake let's say all
surfaces in the room are 100% reflective). There is a single light
source in the ceiling which is sending photons bouncing back and forth
off the mirrors. If the light source is switched off one assumes the
room will go dark. Why is this the case though? Why don't the photons
already emitted from the light source continue to be reflected around
the room ad infinitum (i.e. why doesn't the room stay bright)? Why would
shutting off the light source affect photons that have already been
emitted?
ANSWER:
There is no such thing as a perfect mirror. If
there were, you had better not leave the light on too long since the
light will continue to increase because there is no loss. When you turn
it off, the light would remain bouncing around. Suppose that the mirrors
were 99.99% efficient, far better than the best mirror, and the walls
were 3 m apart. Then in one millisecond (10-3 s=0.001 s), the intensity
of the light would be reduced to about 1/22,000 of its original
intensity! So the real world can impose pretty big constraints on ideal
situations we can dream up.
QUESTION:
Why does the front and rear
window of my car frost up during winter while the side windows mostly
get a bit moist?
ANSWER:
I am not really sure, but I believe
that it may be because the side windows are vertical whereas the front
and back are not (but the back is in SUVs and vans). This allows them to
radiate toward the sky more easily. I know that this is not clear, but I
have answered similar questions three times before and if you read those
answers (click here and follow the links as you go) you can follow my
reasoning in my guess to your question.
QUESTION:
the speed of
light is a constant. If i were in a spaceship traveling at half the
speed of light, one would think that a beam of light passing by me would
appear to me to be moving at half the speed of light, but since the
apparent speed of light is an inependent constant time would dilate
(slow down) for me in order to maintain an apparent velocity of 300,000
km/s. In essence time has been manipulated in order to maintain an
apparent velocity equal to lights absolute velocity. From this i
conclude that the speed of light is such a constant that time itself
itself will be manipultaed in order to maintain a constant velocity. I
happen to know light travels fastest in a vacuum and slower through a
medium. do you happen to know how this occurs and why time would not be
manipulated (dilated) in order to prevent light from maintaining a
constant velocity?
ANSWER:
The constancy of the speed of light
results in our having to rethink our ideas of both time and space, not
just time as you suggest. But that is not really relevant to your main
question concerning the speed of light in a material. The fact that the
speed of light is slower than in a vacuum has nothing to do with
relativity. I have previously answered a similar question.
QUESTION:
Why are some object transparent? Why do some gases have colour and some
don't?
ANSWER:
It all depends on the atomic or molecular
structure of the object or gas. Let's take gases as the example. When
light shines through a gas it might interact with the atoms. If the
energy of the light is just right, a photon might be absorbed by an atom
and excite it to an excited state; then, quickly, that excited atom
drops back to the original atom and emits a photon of the same energy as
the one originally absorbed. But the new photon is radiated in a random
direction, so you would see it and the gas would appear to be that
color. For example, if yellow light could be absorbed then the gas would
look yellow in color. But suppose that there were no states in the atom
which could be excited by visible light; then all visible light would
pass right through and the gas would be colorless; we would say that
this gas is transparent.
QUESTION:
IF GRAVITY IS NEGLIGIBLE AT
THE ATOMIC LEVEL, WHY THE GRAVITATIONAL FIELD OF A STAR, FORCE LECTRONS
TO FUSE WITH PROTONS, CREATING NEUTRONS? ISN'T THAT A BIG INFLUENCE OF
GRAVITY UPON ATOMS?
ANSWER:
When people say that gravity is
negligible on the atomic level, they mean that, for example, the
gravitational interaction between an electron and a proton if negligible
compared to their electrical interaction. When in a sufficiently intense
gravitational field, any object with mass will respond. And any atom
experiences gravity; that is why the earth's atmosphere does not fly out
into space.
QUESTION:
The speed of light moves @ constant
velocity & hence is not accelerating. This means that dv/dt = 0. This is
the speed limit that nature imposes & nothing can travel any faster. For
there to be an acceleration there must be a change in velocity, so if I
shoot fireworks into the night sky ( say a Roman candle) & at a later
time (dt), I see a flash, hence light. Before the flash occurred, there
is only the core material launched & the light didn't exist because the
explosion hadn't yet occurred. To me this means the light had an initial
velocity = 0. Did the light not have to accerlate from v = 0 to v =
constant? I had a change in velocity, hence, the light had to accelerate
initially?
ANSWER:
You say that the light did not exist before
the explosion. That is the key—it is created already having the speed c.
In terms of photons, they are created having a speed c and are absorbed
by being annihilated without slowing down. In terms of waves, there is
some kind of "antenna" (imagine a charge on a spring) which has both
electric and magnetic fields which are time varying and propogate with
speed c. (Imagine that a charge is created (as in pair production); the
electric field from that charge will appear to an observer a distance d
away after t=d/c seconds because fields propogate with speed c.)
QUESTION:
Friends and I are discussing: If a ball is perfectly
elastic and it is released over a surface that is also perfectly
elastic, and there are no other sources of friction (like air) and no
other ways for the ball to lose energy, will the ball continue bouncing
forever? Of course these restrictions can never be realized. The
question evolved into: Does gravity alone, independent of any other
pathways of lost energy like friction, contribute to the successive
lower bounces of the ball and the ball's coming to rest? Some are saying
that gravity alone contributes to the successive lower bounces; I think
this cannot be true.
ANSWER:
Of course, this is a completely
hypothetical question, as you note. Let me start on a seemingly
unrelated topic: some binary star systems, two stars rotating around
each other, are observed to be gradually losing energy for no apparent
reason. In the theory of general relativity, accelerating masses will
radiate energy much as accelerating electric charges radiate energy in
the form of electromagnetic waves (it is how an antenna works). The
gravitational radiation is usually referred to as gravitational waves.
Gravitational waves have never been directly observed but there is an
active program to try to detect them. If you calculate the energy
predicted to be radiated by the binary stars referred to above you get a
very good match with measured rates, so this provides the best evidence
we have so far for gravitational waves (indirect evidence). Your
hypothetical ball is constantly accelerating and should therefore
radiate energy away and eventually stop bouncing. I don't know how to do
the calculation, but I suspect the time for the ball to lose its energy
would be extremely long (like you would probably notice no measureable
effect in your lifetime or the lifetimes of many generations to come).
QUESTION:
1)IF A PHOTON IS ABSORBED BY AN OBJECT, AND THAT OBJECT
EMITS ANOTHER ONE, BOTH PHOTONS WOULD HAVE THE SAME VELOCITY? 2)IF A
PHOTON IS ABSORBED BY AN OBJECT AND THAT OBJECT EMITS ANOTHER ONE IT
WOULD STILL BE THE SAME PHOTON, OR WILL IT BE THE SAME PHOTON WITH A
DIFFRENT FRECUENCY? 3) WHEN ARE TWO PHOTONS THE SAME?
ANSWER:
It makes no sense to talk about a photon being the "same photon" in
quantum mechanics. If two photons exist in the same quantum mechanical
system, they are identical particles and cannot labeled because their
identity can be mixed, that is a particular photon might be 10% of
photon A and 90% of photon B. Essentially, your questions are not
meaningful in quantum mechanics.
QUESTION:
according to the laws
of physics, friction does not depend on surface area. Why then do
Formula 1 cars not have narrow tyres and wheels to save weight?
ANSWER:
The so-called "law of physics" is, presumably, f=mN. This
is not a law of physics, it is an empirical reltaionship which is
approximately true under restricted conditions. Friction is a very
complicated thing, not the simple thing normally presented in elementary
physics courses. I have previously answered your question, so have a
look there.
QUESTION:
Has anyone ever suggested a place for
tachyons in the Standard Model or any other model of particle physics?
ANSWER:
I am not aware of any inclusion in the standard model. It
is apparently of interest in quantum field theory. See the Wikepedia
entry on tachyons.
QUESTION:
The speed of light and gravity. Is
the speed of light restricted to the speed at which gravity propergates,
if so why? Or is it the case that both gravity and the speed of light is
restricted to some other cause like say the speed of the expanding
universe or currently where we are in the universe. Further to my
previous question, is the speed restriction on the photon caused at the
point of where it is released from the atom or is it forced on it all
the way along it's journey through space by the fabric of space time
itself, or even both?
ANSWER:
The speed of light is a universal
constant, it depends neither on the source nor the receiver nor the
"fabric of space." The speed of gravity has never been measured but is
widely assumed to be equal to the speed of light. See my earlier answer
on this question.
QUESTION:
what is RADAR,end howe did worked
ANSWER:
Radar is an acronym and stands for radio detection and
ranging. The basic idea is that radio waves are transmitted and when
they encounter something they are reflected. If you then detect these
reflected waves you can deduce the distance of the reflector by the time
of travel, the direction toward the reflector using a directional
receiving antenna, and the speed of the reflector by observing the
Doppler effect on the detected waves. I would urge you to read the
Wikepedia entry on radar.
QUESTION:
what determines how long an
electron stays in an excited state?
ANSWER:
The lifetime of a
state is determined by something called the matrix element. Essentially
this quantity includes the wave functions of the initial and final
states and a mathematical object (called the transition operator) which
describes the type of transition. Various transitions are allowed for
any pair of states characterized by things called multipolarity like
electric dipole, magnetic quadrupole, etc. Hence the decay of one state
to another generally has many lifetimes corresponding to different
multipolarities; one is usually much more probable than all the others,
though, and will be the shortest lifetime. The larger the matrix element
is the shorter the lifetime.
QUESTION:
Why does a wave with a
short wavelength not diffract as much as a wave with a longer
wavelength.
ANSWER:
How do you quantify diffraction? What does
"diffract as much" mean? Suppose we take, as an example, single-slit
diffraction: the longer the wavelength the more spread out is the first
maximum in the diffraction pattern. The equation for the location of the
first minimum is sinθ=λ/W where λ is the wavelength and W is the width
of the slit. So the angular width is approximately 2λ/W. Since this is
proportional to the wavelength, longer wavelength is more spread out.
You can see this at this site.
QUESTION:
Based on the principal
of binding energy when we burn fossil fuels we are reducing the net mass
of the earth. So how much mass has the earth lost from burning fossil
fuels (coal, oil, and natural gas) in the last 100 hundred years.
ANSWER:
Assuming that the released energy does not escape from the
earth, the total mass of the earth does not change; this is because of
conservation of energy of an isolated system.
QUESTION:
My 8 year
old asked me if gravity has the same effect on water vapor as for
everything else. I thought this an interesting question and wondered
about the effect of heat on gases and what about mass? I thought that
mass was not a factor in gravity's effect.
ANSWER:
Gravity has
exactly the same effect on any object: the object experiences a force
which is proportional to its mass. This force is called the weight of
the object. So, yes, gravity affects water vapor molecule by molecule.
If there were no gravitational force on water vapor, when water
evaporated it would simply fly out into space and all water would have
been long gone by now. By the way, that is why there is no evident water
on the moon—the gravity there is not strong enough to hold its
atmosphere. Keep in mind that weight is seldom the only force on an
object. Consider a dust mote; it appears to float around weightlessly
but it is experiencing forces from the air it is in which keep it from
dropping the same way a bowling ball would.
QUESTION:
I want to
know what is the force behind electrons in a moving circuit. I want to
know what makes them move. Explain what potential difference is.
ANSWER:
The potential difference between the ends of the wire
causes there to be an electric field inside the wire. This field exerts
a force on the electrons which then move. If there is a potential
difference between two points in space this simply means that a charged
particle between those points will experience a force. Positive charges
will experience a force towards lower potential and electrons will
experience a force towards higher potential. Potential is related to
potential energy of a charge in a field. If the potential energy of a
charge Q is U then the potential at that point is V=U/Q.
QUESTION:
This is a question about why optical fibers are designed the way they
are. I know that an optical fiber has a center core of glass with a high
index of refraction which carries the light signal. There is an outer
cladding of transparent material around the core which has a lower index
of refraction than the core. The light signal is confined to the core
because it reflects off the interface between the core and outer
cladding due to the difference in index of refraction. My question is
this: why don't they simply use a single glass fiber with a uniform
index of refraction and coat the outside of the fiber with mirror
silvering so that the light signal is confined to the inside to the
fiber by mirror reflection? In other words, why is the index of
refraction interface better for confining the light than a mirror
surface?
ANSWER:
The kind of reflection which occurs in fiber
optics is 100% efficient, that is no light is lost. It is called total
internal reflection and occurs when a boundary with another medium with
smaller index of refraction is encountered at an angle greater than the
critical angle. In principle, one could just have a glass fiber in air
which has an index of refraction smaller than glass; the sheathing is
just for uniformity. A mirror, on the other hand, is not very efficient,
maybe only something like 90%. 90% sounds good, but when you think of
the millions of reflections the light undergoes, you quickly end up with
almost nothing—0.91,000,000≈0.
QUESTION:
is it considered
possible that space has a structure , Iv;e read (popular magazines and
science channel) that some physicists believe that it is like a lattice
, foam, or granular fluid and if so could it flow like a fluid? what do
they theorize it might be composed of ?
ANSWER:
You are
essentially asking whether space is quantized. I have previously
answered this question; the answer involves what is called the Planck
length. It is certainly not possible with present knowledge to prove
that space is discretized.
QUESTION:
I would like to know what
causes a charge at the atomic level. I know that if you were to have
more electrons than protons then you would have a negative charge. Or
even at a more basic level what causes quarks to have fractions of a
charge? What causes an electron to have a negative charge?
ANSWER:
See the answer below. Electrons and protons have equal but opposite
charges. The electron's charge being negative is a arbitrary; it simply
must be opposite that of the proton.
QUESTION:
If
electromagnetism is conveyed by photons, why is electricity considered a
flow of electrons? Why isn't it a flow of photons?
ANSWER:
The
photon, as you correctly state, is the conveyer of the force. Electric
current, by definintion, is the flow of charge and photons have no
charge. Some signals are conveyed by flow of photons: when pulses are
sent down a fiber optic cable it is light which carries the information
much as electrons do in a copper cable. Come to think of it, light from
a light bulb is a flow of photons.
QUESTION:
Hello, I'm a high
school student and I have a few questions which are probably very
annoying. For most of these things I have only been able to get circular
or abstract meanings which don't explain HOW and WHY these things occur.
Here's one of them: 1) What is charge actually? (not just when it's said
that an atom is charged because it has more positive/negative
protons/neutrons etc., but also the charge that forms electric fields.
In other words what exactly are coulombs measuring, and what DOES and
electric current consist of?). Thankyou!
ANSWER:
The problem
often is that people don't know what physics is. In many instances,
particularly at the foundations, we are compelled to be empirical, to
simply acknowledge that some things are because they are. We begin doing
physics by looking around at forces in nature. We feel our own weight,
the force the earth exerts on us because we have mass and, through many
experiments and calculations, we discover that two objects that have
mass exert forces on each other. But we don't really know what mass is,
do we? It is a property that most things in the universe have which
allows them to exert and feel gravitational forces. That may be
unsatisfying to you, but sometimes it is the best science can do. Armed
with our experience studying gravity, maybe we now look around for other
kinds of forces in nature. One day when combing our hair we notice that
there seems to be a mysterious force which attracts our hair to the
comb, seemingly having nothing to do with gravity. We start doing
experiments and make a remarkable discovery—some objects in the universe
possess a new property which we decide to call electric charge which
allows them to cause and feel this new force which we call the
electromagnetic interaction. It is a force much stronger than gravity
and may be either attractive like gravity always is or repulsive; hence
we conclude that there are two different kinds of charge whereas there
is only one kind of mass. But what actually is charge? We really don't
know, we simply infer its existence by observing nature.
QUESTION:
ordinarily, in order to find the electrical current through a conductive
medium one can utilize Ohm's equation and simply divide the electric
potential by the overall resistance of the medium through which the
electricity travels, but if one were to attempt to find the electrical
current through a superconductive medium by using Ohm's law one would
have to divide the electric potential by an overall resiatnce of zero,
making the electrical current, In theory, infinite. I know in actuality
this can't be the case. How would one find the electrical current
through a superconductive medium if Ohm's law is not applicable?
ANSWER:
Ohm's law is not really what I would call a law because it
is something only approximately true for only some materials. So,
technically, Ohm's law will not tell exactly what the current is in
anything. In a super conductor imagine you get 10 amperes of current
flowing; it will continue to flow forever dependent on nothing and so
you would have to simply say the "law" is I=10 for this situation. Now
go in and increase the current to 20 amperes; now the "law" is I=20. How
can you cause a current to flow? Just momentarily attach to a battery or
use a changing magnetic field to cause an induced current.
QUESTION:
I am a high school student, currently having a debate with my friends
about existence of "coldness" As an active pursuer of philosophy, I was
taught that there is no such thing as "cold" - It is only the absence of
heat. However, as my knowledge extends only so far, I have no confidence
nor proper knowledge to effectively pursue my friends of this simple
concept when the debate turns into a science debate. So I ask you, if,
scientifically, "cold" is merely a word to describe the absence of heat
(or the movement of molecules, for that matter)
ANSWER:
Hot,
cold, warm, cool, tepid, lukewarm, scalding, icy,… These are all
qualitative words which give us qualitative information about the
temperature of something. So, the pertinent question is: what does
temperature measure. In physics, temperature is a measure of the average
kinetic energy per molecule of the object. (Kinetic energy of a mass m
with a speed v is ˝mv2.) This is actually what temperature is for a gas;
for a solid it is a little more complicated but essentially comes down
to average energy per molecule. So, when we say one object is colder
than another it does not mean that it has more of something called
coldness as suggested by your friends; rather it means that it has less
internal energy per molecule, the molecules are jostling around with
less speed than something not so cold. Incidentally, your use of the
word heat is incorrect; but don't feel badly because lots of physicists
use it incorrectly too. Heat (Q) should be reserved for energy which is
transferred from one object to another whereas the temperature of
something is determined by its internal energy (U). The first law of
thermodynamics is essentially energy conservation. The change in
internal energy of a system equals the heat which flows into the system
plus the work W done on the system, ∆U=∆Q+W.
QUESTION:
Some 30
years ago I took an electronics course and there was an ongoing debate
over the amount of time it took from when power was first applied to a
circuit to when it was available throughout the circuit. Some said it
was instantaneous, while others argued the point. I was never fully sure
if what they really meant was "relatively instantaneous" (as in the
speed of light), because for all practical purposes there would be no
effective difference in most circuits. Do you have an answer?
ANSWER:
Hell, I have an answer for anything; I might not be right
though, my wife tells me. When you switch on a light it comes on
instantaneously. Or, does it? As you probably know, the drift speed of
the electrons which flow in the circuit are very small, much smaller
than a millimeter per second. However, that which moves the electrons is
an electric field in the wire and when you turn on the switch, the field
appears in the wire at the speed of light, so it is not really
instantaneous, but since the speed is so large, it is for most practical
purposes. There are other effects which make more noticible delays. When
a current starts flowing in a loop, a magnetic field starts building up
and this changing field causes a back emf around the circuit which
opposes the increase of current; this is Lenz's law. Another way of
saying this is that the self inductance of the circuit will keep the
current from changing too fast. So if you had a simple circuit with a
resistor, a battery, and a switch and you watched the voltage across the
resistor with an oscilloscope when you closed the switch, you would see
a time much longer than the speed-of-light time.
QUESTION:
Is
there any study or theory to explain the electrical charge of an
electron as a internal way of motion of the electron?
ANSWER:
No.
QUESTION:
If the rear wheel of a a 3/4 ton car, moving at
10mph, drove over someone's ankle, would that person be able to get up
and walk away withiout a bruise, a mark or injury of any kind?
ANSWER:
I am not a forensic expert, so my opinion should hold no
sway from a legal perspective. This could certainly happen if either the
tire or the ground were soft. Also, if the victim were wearing a shoe
with a relatively strong sole which could support the weight of the car
momentarily.
QUESTION:
I did the following experiment: I parked
one car on my driveway. I parked the other car in the garage but left
the garage door WIDE OPEN. Overnight, the temperature dropped below the
dew point. The garage walls are insulated but the ceiling is not. The
garage is not heated. Result: Frost formed on the windows of the car on
the driveway but not in the garage. I assume that the temperature inside
and outside both cars was the same overnight so why did frost form on
the windows of the car in the driveway but NOT on the car in the garage?
ANSWER:
I have answered similar questions twice before. There
are two important factors in frost formation at temperatures near the
freezing point, radiation cooling and evaporative cooling. My research
has led me to believe that radiation cooling is more important. If you
read my earlier answers, which are much more exhaustive than this
answer, you will see that all things radiate away energy and that tends
to cool them. However, there are also many things in the environment
which are also radiating energy and this energy will be absorbed by its
neighbors, and so everything will tend to be in thermal equilibrium. So,
look at the car in the garage: it, the walls, and the roof are all at,
say, 340 and radiating but also absorbing so all stays at 340 and no
frost forms. Now look at the car outside: its environment is at 340 and
it is radiating accordingly but it does not have the walls and roof from
which to absorb energy and so it cools to a lower temperature and frost
forms. The second factor is evaporative cooling. As you probably know,
since it takes energy to evaporate water, evaporation cools; just take a
damp rag and twirl it around and you will see that it gets cold. If
there is a breeze which would hasten evaporation and the car in the
garage is sheltered from the breeze, this would again give the outside
car the cooling advantage. I have noticed this effect even if one car is
parked in the vicinity of a house and the second is not.
QUESTION:
two walls stand opposite each other. The length between them is L. one
of the walls is moving toward the other at velocity V a bird sits on
that wall starts to fly back and forth at velocity 2V how far will the
bird travel before it gets crushed (assume the bird has no dimension and
that only when the walls meet will the bird be crushed)
ANSWER:
This is a trick question, much easier than it seems. The walls will
smash together at the time T=L/v and during that time the bird will fly
a distance S=2vT=2L. OK, I will admit it—I spent some time trying to
compute the infinite series before I figured this out! But it was kind
of cool because I was able to use simple logic to find that the infinite
series from n=1 to n=∞ of (1/3)n is 1/2 which I could not do
mathematically because I am not very good at evaluating infinite series.
QUESTION:
Are all coupling constants dimensionless and is this a
strict requirement?
ANSWER:
This is mainly a case of semantics.
A coupling constant is something which tells the strength of an
interaction; for example, electric charge could be thought of as a
coupling constant for electrostatics or mass as a coupling constant for
gravitational forces. However, field theorists prefer to work with
quantities which do not depend upon the system of measurement and so
coupling constants are usually defined in such a way that the constant
is dimensionless.
QUESTION:
Thank you in being available for this
type of thing. I chat at physorg and I learn alot, but there are some
cranks who state things of opinion as fact. Please laugh at this
question! A member of physorg is adament that the neutron is the force
carrier for gravity. Myself and 2 or 3 others are trying to explain why
and how that can't be and why the graviton fits with our current
knowledge, but he continues to claim he is correct. Could you please
come up with one statement of why this is impossible so that I can quote
it to him. There must be a perfectly clear answer that even he has to
recognize as fact, yes?
ANSWER:
The current theory of gravity,
general relativity, attributes the gravitational force to geometric
effects, the warping of space-time by the presence of mass. There is no
successful theory of quantum gravity, that is the field has not been
successfully quantized thereby allowing identification of the "force
carrier". There is no such thing as a graviton, it is only a qualitative
idea at this time. So, your nemesis thinks maybe the neutron is the
graviton, right? Here is what is wrong with that:
To the best of our
knowledge, the gravitational force propogates with the speed of light.
The neutron, being a particle with mass, cannot travel the speed of
light. In fact neutrons, having no charge, are quite difficult to
accelerate and are usually relatively slow in nature. The neutron is not
a stable particle unless it is bound inside a nucleus; a free neutron
has a lifetime on the order of 15 minutes at which time it will decay
into a proton, and electron, and an antineutrino. This would not be very
good for communication of the gravitational force between, say, the sun
and Jupitor would it?Forces which have carriers with mass, for example
the strong nuclear interaction with mesons as field quanta, are very
short ranged. Gravity is a long-range interaction like electromagnetism,
that is it falls off like 1/r2. The force carrier for electromagnetism
is the photon which is massless and one would therefore expect the
graviton to be massless.
QUESTION:
is energy quantized ?
ANSWER:
If a system is bound, its possible energy states are
discrete or quantized. If a system is unbound, its possible energy
states are continuous (not quantized).
QUESTION:
Sorry in advance
for what may be a overly simple question; but after watching various
lectures on particle physics I was wondering is there an actual proton,
or is a 'proton' now verbal shorthand for the two up & one down quarks
which make up a proton? Or in other words, after you remove
(theoretically of course) the three quarks which define a proton, is
there anything left?
ANSWER:
This is just a matter of semantics,
isn't it? Would you say that there is no "actual" hydrogen atom because
we know it to be composed of an electron and a proton?
QUESTION:
Are power density and specific power the same thing? I know power is
work per unit time. Seems they would have different units--power
density--power per volume and specific power -power per unit mass. The
same for energy density and specific energy.
ANSWER:
I never
heard of power density or specific power. It turns out, according to
Wikepedia, that they are engineering terms and are apparently
synonymous, both meaning power per unit mass. In physics energy density
is energy per unit volume. Specific energy is apparently energy per unit
mass but I have not seen this quantity used in physics except in the
context of specific heat.
QUESTION:
Is there (potentially or
actually) light in the universe we cannot or potentially cannot DETECT
(or see visually) on our color spectrum systems? Does all light in the
spectrum we know about/see, travel at the same speed: light speed?
ANSWER:
By definition, light is the portion of the electromagnetic
spectrum to which our eyes are sensitive. It is a tiny part of the whole
spectrum which includes also radio waves, ultraviolet radiation, xrays,
gamma rays from nuclei, infrared waves, etc. All electromagnetic
radiation travels with the same speed in vacuum.
QUESTION:
how
law of conservation of energy is not voilated in step up & step down
transformer
ANSWER:
Because it is not the law of conservation of
voltage. You may not draw more energy from a transformer than you put
in. Since the power is VI, the power input VI must equal the power
output VI. For example if you have a transformer which has a step up
factor of 10, you may only have a current 1/10 of the current supplied
to the primary. (Your email address is not valid.)
QUESTION:
Does
a kernel of popped popcorn have the same number of calories as it had
before it was popped? Do not consider that it is fried in butter, or
that tiny particles of the popcorn fly off when it is popped. My friend
suggests that it uses energy (calories!) in the popping process, I
believe it simply is releasing energy it has received in the heating
process, which cause moisture in the kernel to turn to steam, expanding,
and creating the "popping". Do total calories remain the same before and
after?
ANSWER:
The first thing we should acknowledge is that
what "cooking" does is change the chemical composition of whatever you
are cooking, and changing the chemistry inevitably changes the caloric
content. That said, let's examine what happens when you "cook" popcorn.
The water inside the kernel becomes superheated and the hull cannot
contain the increased pressure and the kernel explodes. When this
happens the starch contained in the kernel expands rapidly which is what
the popcorn is. The rapid expansion causes cooling which tends to keep
the starch from undergoing a chemical change, and therefore popping corn
is, to a large extent, not really cooking. So, in my judgment, you are
correct: the caloric content is not much changed by the popping.
QUESTION:
Can you please explain electron spin? It does not seem to
fit in with the model I have been taught of a cloud of electrons
'orbiting' a central nucleus.
ANSWER:
The earth orbits around
the sun. Therefore the earth has an angular momentum called orbital
angular momentum. The earth rotates about its own axis. Therefore the
earth has an additional angular momentum which we could call spin
angular momuntum. The spin angular momentum has nothing to do with the
orbital angular momentum.
An electron orbits around the nucleus (or,
more sophiscatedly has a wave function which contains the information
about the electron cloud). The electron has an angular momentum called
orbital angular momentum, the information about which is also contained
in its wave function. Like the earth, the electron has an additional
intrinsic angular momentum which we call spin angular momuntum. It is as
if the electron were spinning on its own axis (although that classical
idea has problems if taken too literally). The spin angular momentum has
nothing to do with the orbital angular momentum (or the electron cloud).
QUESTION:
How to derive E=m.c.c?
ANSWER:
You should be
able to easily find this in any physics text. I have outlined the
derivation in an earlier answer. You basically calculate the amount of
work necessary to speed an object of mass m up to a speed v and call
that the kinetic energy.
QUESTION:
For a non-scientific person,
what would be an explanation of the term "array" when used in
discussions regarding lasers? (i.e. medical lasers or ipl)
ANSWER:
This simply means a bunch of something. Array usually implies that they
are arranged in an orderly way.
QUESTION:
the situation is this
you use the elevator in the mall and you put a weighing scale inside the
elevator you measure your weight and mass due to explain the second law
of motion. is there changes in your weight as you go up as you go down?.
if there changes, what is the reason of it changes. what is the
scientific principle of it?
ANSWER:
Your mass is a measure of
how much matter there is in you. Being in an accelerating elevator
cannot change that. Your weight is the force which the earth exerts on
you. Being in an accelerating elevator cannot change that. What changes
is your apparent weight, how heavy you feel. You can determine this by
looking at a scale on which you are standing; this scale does not really
measure your weight but rather the force with which you push down on it.
If you are accelerating, Newton's second law says that the net force on
you will not be zero and the only forces on you are the scale (up) and
you weight (down). [Keep in mind that the force the scale exerts up on
you is equal and opposite to the force you exert down on it because of
Newton's third law.] If you are accelerating up (either going up
speeding up or going down slowing down) you will feel heavier. If you
are accelerating down (either going down speeding up or going up slowing
down) you will feel lighter.
QUESTION:
How close are scientist
to developing a super laser similar to the weapon used in the death star
in star wars or is it even possible to develop such a weapon. If it is
no t possible to make a laser like that then what is some of the
weaknesses of this model and please explain why it cannot be done if
possible.
ANSWER:
Nobody is even considering trying to develop
such a weapon. The reason is very simple—we do not have access to the
amount of energy it would take to operate it. If you were to totally
blow apart an earth-sized planet the total energy you would have to
supply is about 1032 J; to calculate this, just use the magnitude of the
total gravitational potential energy of a uniform sphere is, 3GM2/(5R).
Now, the death star took about one second to blow up the planet, so the
power had to be 1032 W=1026 MW. The entire power output of the US is
about 106 MW, about a million megawatts. So it takes a mere 1020
Americas delivering all their energy in a second to fuel the death star
laser.
QUESTION:
Eart pulls the yo-yo downward and the yo-yo
pulls earth upward.Which of Newtons laws explains this?
ANSWER:
The third.
QUESTION:
What happens tp particles at 0K?
ANSWER:
It cannot happen, quantum mechanics forbids it. You can
extrapolate from nonzero temperatures and conclude that all the
molecules would be at rest, but you can never really get there because
the Heisenberg uncertainty principle says that you cannot know the
velocity exactly if you have any knowledge at all of the position of the
particles.
QUESTION:
If light beams bend in the presence of mass,
then, if we view the entire universe as a pretty large mass, then all
light beams must be bending. That means that 2 light beams departing an
object in different directions might eventually cross each other's path
(might take a few billion years but might happen). Is it possible,
therefore, that, when we look up into the sky, we might be seeing the
same object more than once - as x light-years away in one direction and
y light-years away in another? If we see this object at very different
ages then there might be no way to determine that we are, in fact,
looking at the same thing.
ANSWER:
In fact this has been
observed many times in an effect called gravitational lensing. If,
between us and a distant galaxy, there is a very massive and compact
object, light passing to the right and to the left will both be bent,
for example. In that case we will see two images of the same galaxy.
More commonly, one just sees blurs or streaks of light from the source.
Some nice images may be seen here. Your hypothesis that something could
have images at very different times because of very different path
lengths is unlikely since the intensity of the earlier image would be
hugely reduced because of the much longer distance the light had to
travel.
QUESTION:
What is the definition of a megarod (pertaining
to radiation)?
ANSWER:
I think you must mean megarad. One rad is
the amount of radiation which will deposit 0.01 J of energy in 1 kg of
material. So, you see, a different amount of radiation will be 1 rad for
steel than for human flesh. A megarad would be 106 rad. Incidentally,
the rad is an obsolete unit and radiation doses are now more often
quoted in Grays (Gy) where 1 Gy=100 rad.
QUESTION:
Does the
orbital velocity of a meteoroid at the Earth's distance from the Sun (in
space) depend upon the eccentricity and size of the meteoroid stream?
Are the speeds of meteors from meteor showers the result of two vectors:
the Earth's orbital velocity and the meteoroid's orbital velocity?
ANSWER:
I really do not understand what the first part of your
question is asking. Certainly the velocity of any object in orbit around
the sun depends on the orbit and where the object is on that orbit. If
we view the velocity of a meteoroid on the earth, then the velocity we
see will be the the velocity of the meteoroid relative to the sun minus
the velocity of the earth with respect to the sun, vME=vMS+vSE=vMS-vES
where, for example, vMS is the velocity of the Meteoroid relative to the
Earth. This ignores the fact that we also have a velocity due to the
earth's rotation about its axis.
QUESTION:
is it possible to
prove that there is a mimimum size X and nothing can be smaller than X ?
I seem to recall this may be Planks constant. A similar analogy is there
is a maximum speed ie C and nothing can go faster than C
ANSWER:
You are essentially asking whether space is quantized. I have previously
answered this question; the answer involves what is called the Planck
length. It is certainly not possible with present knowledge to prove
that space is discretized.
QUESTION:
What is gravity at the
sub-atomic level
ANSWER:
Negligible.
QUESTION:
I assume
the earth performs work in keeping the moon within its orbit about the
earth, otherwise the moon would just fly off into space. As it performs
work is expends energy. Further I assume there is a minimum size that
something can be as everything is composed of waves. The smaller
something is the smaller the wave the shorter the wavelength. Wavelength
is proportional to the energy the wave contains. If a wave has
infinitely small wavelength then it has infinite energy within a finite
volume and therefore infinite energy density. As energy density is
proportional to an objects gravity infinite energy density means
infinite gravity. From the above I conclude that gravity does not expand
out into space for an infinite distance as the amount of work done by
the earths gravitational field on a planet billions of light years from
earth would be so small that it would be smaller than the minimum sized
object…is this right?
ANSWER:
Consider a book sitting on your
desk; since it does not fly off into space the earth must be doing work
on it, right? Wrong. Just because one object is bound to another does
not mean work is being done on it. So, first examine the moon situation:
let's start out making the approximations that the moon's mass is
negligible compared to the earth's and that the moon's orbit is
circular; these are both approximately true. Then, since the moon's
velocity is always perpendicular to the gravitational force it feels, no
work is done. Hence, to an excellent approximation, the earth does no
work on the moon. Now the more general case: If the moon's orbit is such
that the moon is getting closer to the earth, the earth is doing
positive work on the moon and if the moon is getting farther away, the
earth is doing negative work. But, the moon exerts a gravitational force
on the earth which is exactly the same magnitude as the force which the
earth exerts on the moon but in the opposite direction (Newton's third
law); therefore the moon is always doing work on the earth which is just
the negative of the work which the earth does on the moon, so the net
work done by the earth-moon system is zero, that is the total energy of
the system does not change.
Your statements regarding wavelengths of
particles are incorrect. A bowling ball going 100 mi/hr has a much
shorter wavelength than an electron going the same speed. Wavelength is
not determined by size of the particle.
I have no idea what you are
trying to say about infinite gravity etc., but it probably doesn't
matter because it seems to be based on your ideas of wavelength.
QUESTION:
If you are using a laser to cool an atom, the momentum of
a collection of photons is used to in a way counteract that of the atom.
So if you have an atom moving towards the right, it hits a photon
traveling towards the left, tuned to the resonance frequency of that
atom and hence is more likely to be absorbed. The tiny amount of
momentum that the photon has is transferred to the atom in the opposite
direction to the direction of travel and hence slows the atom down.
However what i would like to know, is that once the atom has absorbed
the photon, it cannot stay in that excited state forever, so surely
eventually it must emit another photon in a direction which is totally
random i believe. As the photon is emitted will it not give the atom a
slight kick in another direction? Considering the direction of emission
is totally random i would like to know why laser cooling is still so
effective at cooling atoms.
ANSWER:
A thousand small kicks
opposite the direction the atom is moving will make a significant change
in the speed of the atom. A thousand small kicks in random directions
will average out to just about zero change in the speed of the atom.
QUESTION:
Is gravity a byproduct of electromagnetism or somehow
related to it.
ANSWER:
Nobody has ever successfully unified
electromagnetism and gravity; there is no known relation between the
two. Interestingly, Einstein, after completing the theory of general
relativity (which is our best theory of gravity) in 1916, spent the rest
of his life (he died in 1955) trying to develop a unified field theory
which would unite the two forces but with no success.
QUESTION:
Hello, I would like to know how much time passes on earth, doing one
light year. The reason I'm asking this question, years ago, I read an
article about traveling to the Andromeda Galaxy from earth at the speed
of light and return. The article said the earth would 300 million years
older when you return. I seen other articles on the internet suggesting
2, 4, and even 20 million year would pass. So what would be the correct
time passage on earth? Could you also tell me in layman terms, how you
came up with the anwer, Thanks!
ANSWER:
For starters, your
terminology needs some touching up: a light year is a distance, not a
time; it is the distance light will travel in one year. Second, no
material object may go the speed of light, so your question technically
has no answer. Now, Andromena galaxy is about 2.5 million light years
from earth. Now, let's assume that the spaceship is going 0.99999 the
speed of light. Then from earth's perspective it will take almost
exactly 5 million years for the round trip so the earth will be that
much older. The ship, however, will see the distance to be only
2.5√(1-.999992)=0.011 million light years=11,000 light years so the time
for the trip as measured by clocks on the ship would be about 22,000
years.
QUESTION:
If you had 2 trains traveling side by side
Train A. at top speed and Tran B. at half of that speed. As the two
trains are traveling along Train B. is ahead of Train A. but as Ta is
about to pass Tb at the exact moment they are exactly side by side
lightning strikes 1000meters ahead of them. Considering the fact that
time slows down the faster you travel, which Train driver would see the
lightning strike first? i believe if it was possibale to measure, the
Train driver travelling slower (Train B.) would see the light first.
This is similar to einsteins thought experiment.
ANSWER:
I
believe the key here is length contraction. A train with speed v will
measure the distance to the light source not as 1000 m but as
L=1000√(1-(v2/c2)) where c is the speed of light. He will see the light
approach him with speed c regardless of what v is (the basic postulate
of special relativity) and, while the light approaches him he is
approaching to meet it. So, calling t the time (measured by the train)
until the light is seen, we can write ct=L-vt. Doing a little algebra,
you will find that t=(1000/c)√[(c-v)/(c+v)]. Note that the larger v is,
the smaller t is; so, as measured by the clocks on the trains, the
faster train sees the light first.
QUESTION:
Please explain why
a magnet does not drop straight through a copper tube.
ANSWER:
The magnetic field of the magnet moves with it so the magnetic field
experienced by the copper is changing with time as the magnet drops.
However, Faraday's Law states that a time varying magnetic field will
induce an electric field and this electric field will cause an electric
current to flow in the copper. This electric current will have an
associated magnetic field which will exert force on the magnet.
QUESTION:
Does gravity cause an elrctron to orbit
ANSWER:
No. The orbit is caused by the electric force. Gravity is totally
negligible on the atomic level. I have previously answered a similar
question.
QUESTION:
how does the magnatism of the sun and the
magnatism of the earth affect the earths orbit ?
ANSWER:
In no
measurable way. Magnetism is totally negligible here.
QUESTION:
does Atmospheric pressure effect ones weight on a plant.
ANSWER:
The atmosphere does not affect weight since weight is the force of
attraction to the earth. However, one's apparent weight is affected
because there is an upward buoyant force which adds to the weight force
to make the weight appear less; for example, a helium balloon has a
greater buoyant force than weight and so it appears to have negative
weight. A more thorough discussion of this may be seen in an earlier
answer.
QUESTION:
If an object is traveling east with a
decreasing speed the direction of the objects acceleration is: 1-North
2- south, 3 east. 4- west? My grandson was given this question in a
physics work book the answer the teacher gave was 4-West. I believe the
answer to be 3-east. I believe the book for H.S. students is trying to
give one familiarity with the definition of acceleration which is a
change in velocity and or direction. Since the object is slowing down
(constant speed) it is accelerating ie its velocity changed ie in the
negative. I know that velocity and acceleration are vectors and that
speed is not etc.amI correct ie it accelerates in the direction it is
going east but is negative. I understand that Physicists do no like to
use the word decceleration.Kindly help since my grandson and I have
differing opinions.The teacher is a biologist who is also teaching
physics. There is no disrespect but simply I want to know since I am
quite interested in this.
ANSWER:
What you are saying is
incorrect, the teacher's answer is correct. An object speeding up has an
acceleration vector in the direction of the velocity vector; an object
slowing down has an acceleration vector opposite the direction of the
velocity vector. The negative sign which your argument deduces is
correct and means that the vector representing the change in velocity,
which is tells the direction of the acceleration, is opposite the
velocity.
QUESTION:
I've used this: "all energy will go from high
to low spontaneously" as a rule-of-thumb definition when explaining
events in the context of the Second Law of Thermodynamics. I haven't
found a shorter or simpler explanation, but now I've been told that my
rule-of-thumb definition is wrong. I don't think it is wrong and the
person who told me it was wrong is not a physicist, but perhaps you
could show me where it is wrong? And, if it is wrong, could you give me
a short and simple rule-of-thumb definition that I could replace it
with?
ANSWER:
You have to be careful when you throw around the
word energy. Also, your definition does not state high or low what. If
you mean that "heat cannot spontaneously flow from a material at lower
temperature to a material at higher temperature", then your statement of
the second law is correct.
QUESTION:
As a non-scientist doing
primary science teaching - I have a problem and I can't work out the
answer. Doing stuff using a toy car on a ramp, it seems that the heavier
the vehicle, the faster it is going at the bottom and consequently the
farther it goes at the end of the ramp. My gut reaction is that the
heavier vehicles have better axle construction, so less friction - and
it is this not their mass that causes the difference. I have done maths
and know about KE and PE and I cannot see how the extra mass would in
fact increase the velocity, although the momentum would be greater - am
I correct or am I missing something?
ANSWER:
Well, this is very
interesting. A recent question was very similar except that experiment
had just the opposite result, the lighter car went faster! I can only
reiterate that, in simplest physics, with no friction all cars will
reach the bottom at the same time. This is also the result if there is
friction but the friction is proportional to the weight (as in the usual
f=µN for sliding friction where N is usually proportional to W). So,
your gut reaction is right—the result of the experiment must indicate
that the friction of the winner is smaller (relative to the weight).
QUESTION:
A ball rebounds one-half the height from which it was
dropped. The ball is dropping from a height of 160 feet and keeps on
bouncing. What is the total vertical distance the ball will travel from
the moment it is dropped to the moment it hits the floor for the fifth
time?
ANSWER:
This is really not physics, it is math. Until it
hits the first time it goes 160 ft; until the second time, 2x(1/2)x160
ft; until the third time 2x(1/4)x160 ft; etc. So the total distance
would be
160+2x(1/2)x160+2x(1/4)x160+2x(1/8)x160+2x(1/16)x160=160x[1+2x(1/2+1/4+1/8+1/16)]=460
ft.
QUESTION:
I'm wondering about the distances between subatomic
particals and that relationship to their size. If the subatomic
particals of all atoms on the Earth, for example, were to collapse to
the point of actually touching each other, what would be its diameter?
ANSWER:
First of all, subatomic particles do not have well-defined
sizes (they are sort of smeared out over space) so "touching" each other
does not really have a definite meaning. However, if we suppose the
protons and neutrons in a nucleus are just touching, we can compress the
whole earth so that its density becomes that of nuclear matter (the mass
of a typical nucleus divided by its volume) and see how big it is. The
density of nuclear matter is about 1018 kg/m3 and the mass of the earth
is about 6x1024 kg. So the volume of the earth compressed to nuclear
matter density would be about 6x106 m3. This would correspond to a
radius of about 113 m, pretty small! Incidentally, this is what happens
to a star when a neutron star forms in stellar evolution.
QUESTION:
me and my friend have been arguing about this for a week and he refuses
to accept defeat unless i get a "credible" source. So here goes: We were
talking about mars has approximately a third of the gravity that earth
does, and he said that is because the ATMOSPHERE is thinner there and it
wouldnt be a third if mars had an atmosphere similar to Earths. This
turned into a debate with him claiming that the atmosphere has
everything to do with gravity and your weight, how do I explain in a way
that makes sense that gravity is entirely about the mass of a planet and
not atmosphere? He says that even if i were right, if the earth all of a
sudden had no atmosphere whatsoever we would all weigh less because
there would be less total mass around our planet. Please help!
ANSWER:
You are correct that the mass of the atmosphere is
negligibly small compared to the mass of the earth, however that is not
the reason why gravity at the earth's surface is independent of what the
total mass of the atmosphere is. If the atmosphere were as dense as lead
and 5,000,000 miles thick the gravitational force of something on the
surface of the earth would be the same as if there were no atmosphere at
all. The reason is that for a spherically symmetric mass distribution*,
the gravitational force is determined only by how mass there is inside
of where you are. One way to convince yourself that this is true is that
if you are at the center of the earth you would experience no weight
because there is just as much mass no matter which direction you look.
Here is one technicality: because the atmosphere is not dense we
normally ignore the buoyant force (although you certainly can't for a
blimp, for example). However, there is a tiny buoyant force which makes
our weight appear to be less (your weight is still the same, there is
just a different force up); hence, your friend is wrong on two counts
since if the atmosphere were less dense as it is on Mars, there would be
a smaller buoyant force so objects would appear to weigh more.
*This
means that the density depends only on how far you are from the center,
not on where you are angle-wise; so everything looks the same at the
north pole as at the south pole, for example.
QUESTION:
I would
like to know what impact did Millikan's oil drop experiment have on
science during and before 1920? Why is the electron charge so important?
What is used for?
ANSWER:
This is a strange question! I believe
that understanding the world around us in as much detail as we can is
required by the human spirit. If you did not know the electron charge
you could have no atomic physics. Experiments like that done by J. J.
Thompson were able to measure the ratio of the charge to the mass, but
to get either you had to measure one independently which is what
Millikan's experient did. So you could say that knowing the charge gives
you the mass and knowing the mass of something is important in physics.
The electron charge is used, like many other fundamental constants, for
understanding the universe; what could be more important than that?
QUESTION:
Where does the word "moment" in "moment arm" come from?
How do the two terms relate to one another in analyzing torque?
ANSWER:
An alternative word for torque is moment, so moment arm is
the distance from the axis around which torques (moments) are
calculated. The torque is generally written as the moment arm times the
component of the force perpendicular to the moment arm. A completely
equivalent writing of torque is force times the component of the moment
arm perpendicular to the force; I call the component of the moment arm
perpendicular to the force the effective moment arm.
QUESTION:
I
am an 8th grade teacher trying to teach Physics. When I make up word
problems for force, am I always using acceleration due to gravity. For
example: I can say a 15 kg object is being accelerated 9.8m/s2, what is
its force? But can I say a 20 kg object is moved 2m/s2 what is its
force? Are not all force problems using gravity as acceleration?
ANSWER:
The basic law is Newton's second law, F=ma which relates
the net force F experienced by a particle of mass m which has an
acceleration a. When a 15 kg object is freely falling the only force on
it is its own weight (assuming no air resistance), so if we measure its
acceleration to be 9.8 m/s2 the weight must be 15x9.8 kg m/s2=147 N
(newtons)=33 lb. For the object of mass 20 kg which is measured to have
an acceleration of 2 m/s2, the net force on it must be 40 N which is
about 9 lb; since its weight is 20x9.8=196 N, there must be other forces
on this object. An object may certainly have an acceleration different
from 9.8 m/s2. For example, a box sliding across the floor might have an
acceleration of magnitude 2 m/s2, that is as each second ticks by the
speed gets smaller by 2 m/s so if it starts with a speed of 10 m/s it
takes 5 s to stop. (We usually say that the accerleration is, in such a
case, negative, but the important thing for 8th graders to understand, I
think, is that acceleration tells you how the speed changes, so you
should think of an acceleration of 9.8 m/s2 as 9.8 (m/s)/s so that if
you drop something it has a speed of 9.8 m/s one second later, 19.6 m/s
two seconds laterr, etc.) If you are in the US, it would probably be
helpful for your students to know that 1 N=0.225 lb since they probably
think in terms of pounds; so a newton is about a quarter of a pound.
QUESTION:
I'm interested in understanding the interactions between
subatomic particles. So I would like to ask two questions. 1. Is there
any thinking or explanation of how the charges between the electron and
proton are so evenly balanced, despite the large difference in their
respective masses? It seems like there would logically be some
underlying similarities that I don't see discussed very much. 2. If
these parcicles are really "smeared" like a probability function, how
can they exist for so long?
ANSWER:
Why would the relative
masses have any correlation with the relative electric charges? If
electrons and protons were not of identical charge, the universe would
be a very different place since atoms would not be electrically neutral.
Since the electric force is very strong, the lack of neutrality of
matter would cause there to be no objects as we know them (the repulsive
electric force would tend to keep objects from coalescing. And, what
does a particle being smeared have to do with its existence?
QUESTION:
If two cars approach each other from opposite directions,
each traveling at a speed of 50 km/h, each car one would perceive the
other as approaching at a combined speed of 50 + 50 = 100 km/h to a very
high degree of accuracy. But two spaceships approaching each other, each
traveling at 90% the speed of light relative to an outside observer, do
not perceive each other as approaching at 90% + 90% = 180% the speed of
light; instead they each perceive the other as approaching at slightly
less than 99.5% the speed of light. Why does this happen?
ANSWER:
Of course I cannot give you a complete explanation since that would
require that I do a complete exposition of the theory of special
relativity. Relativity is the reason. Relativity is based on the
postulate that all observers, regardless or their motion or the motion
of a source of light, will measure exactly the same speed for light in a
vacuum. So, if you measure the speed of some particular beam of light to
be c, somebody moving with the speed of 95% the speed of light relative
to you will measure the speed of the beam to be c also. One of the
consequences of this postulate is that no object can move faster than
the speed of light relative to any other object. Hence, having two
objects have a relative speed of 180% violates this rule. The speed of
light is a universal speed limit. If you are truly interested, you
should learn the theory of special relativity; it requires only algebra
to understand it.
QUESTION:
I have a major question in my mind
and I have not found any website that helps me and so please help me to
answer my
QUESTION:
How is time affected by the amount of mass? For
example: if we put a cart on a slope which is 10.3 g, the result will be
3 seconds... In addition, if we change the mass into 15 g, there will be
an increase of time which will be 7 seconds... ( I have conducted an
experiment exactly like the example above, and I see that the more mass
we put on the cart, the longer time we will get)
ANSWER:
Simple
physics would say that there should be no difference if there were no
friction. Also, if there were friction and it was proportional to the
weight, the times would be the same. However, if the friction were not
proportional to the weight, for example the lighter car had a frictional
force 1/10 the weight and the heavier car had a frictional force 2/10
the weight of the car, the heavier car would have a smaller acceleration
as you have found. See earlier answer on this subject.
QUESTION:
My 8 year old son would like to know if an object is moving faster than
the speed of light, will it cast a shadow.
ANSWER:
The
groundrules of this site clearly state that I no longer answer questions
about going faster than the speed of light. However, I want to encourage
inquiring young minds, so I will make an exception. No object may go
faster than the speed of light or even as fast as light. The reason is
that the theory of special relativity, which is extraordinarily
well-verified experimentally, shows that the energy required to
accelerate an object to the speed of light is infinite and, of course,
there is not an inifinte amount of energy in the universe.
QUESTION:
if you have a car in the air and you fill the tires to 35
psi, when you put the car on the ground the psi stays at 35 with the
weight of the vehicle on the tires. why?
ANSWER:
I have
previously answered this question.
QUESTION:
How far would a golf
ball travel on the moon if hit at a 45 degree angle at 200 km/hour?
ANSWER:
I first checked and found that the speed you indicate is
far less than the escape velocity on the moon. I then assume that the
height attained and the distance traveled will be small compared to the
size of the moon so that I can assume that the moon is flat, just as we
do when we do such calculations on earth. The acceleration due to
gravity on the moon is about 1.6 m/s (compared to 9.8 on the earth).
Then I find (I presume you just want an answer, not all the details) the
ball will be in the air for about 49 s, travel a distance of about 1930
m, and achieve a height of about 483 m. Since these are very small
compared to the radius of the moon, my assumptions are fine.
QUESTION:
Does noise require energy to happen?
ANSWER:
I
presume you mean sound noise. Sound is a wave and sound waves carry
energy. Therefore, the source of the noise must supply energy.
QUESTION:
Somewhat technical question, so I don't know if it breaks
the ground rules. I work in MRI and have had some QM courses a long,
long time ago. But this continues to puzzle me. I don't mind at all
looking it up in the QM books if only I knew what to look under. Could
you provide a reference or the correct "topic" I could read up on? A
charged spin-1/2 particle has a gyromagnetic ratio. For example, a
proton has a QM spin-magnetic moment. When it is placed in a constant
and uniform magnetic field its magentic moment will be at an angle
(about 54.7 degrees) to the direction of the applied uniform magentic
field and it will precess around the direction of this applied, external
field. The proton will radiate as it precesses in the magnetic field.
This can be detected by pickup coils. For example, this is how an MRI
system works. (But I am interested in a single particle case, not in an
ensemble of particles.)
QUESTION:
Where does the energy come from to
drive the precession and the associated radiating process as the
particle precesses? If from the magnetic field, then wouldn't this
"drain", say, a permanent magnet (system of magnets) generateing the
magnetic field? That doesn't seem right (but maybe).... Being in a
uniform magentic field, the gradient of B would be zero. So I guess
there wouldn't be any net translational force on the particle. I think
this is because there would not be any difference in energy between
being at p1=(x, y, z) and being at p2=(x+dx, y+dy, z+dz) so no net force
to translate the particle from p1 to p2. So does the particle just sit
there radiating as it precesses? That doesn't seem right. If it radiates
it should be loosing energy and going into a lower energy state. But
there doesn't seem to be a lower energy state to go into? Or, for every
"bit" of energy radiated it must be getting that amount of energy from
someplace else, but where/how? That is what is confussing to me. If the
magnetic field were not uniform I could see that the particle would
translate into a lower energy state and would convert some of the
potential energy into kinetic energy and radiation energy. But in a
constant uniform magnetic field?
ANSWER: {this answer is not
complete yet, I have to go to a concert!}
Your question is closer to
breaking groundrules for not being concise and well-focused than being
too technical. However, I will answer it because it is interesting. If
you work with MRI, I am afraid I must tell you that you do not really
understand what is going on. If a classical magnetic moment is placed in
a uniform magnetic field it will align with the field. That is what it
wants to do. If it is a quantum mechanical particle (that is it has a
spin angular momentum) it cannot align with the field because the
component of the total angular momentum (which is J=ħ√[3/4]) along the
field direction may be only ±˝ħ. That is where your angle comes from,
cos(54.7)=˝/√[3/4]. It is not really correct to say that the proton
precesses; it is more correct to say that it is equally probable to be
at any azimuthal angle and so many texts describe this situation as
precession. Go ahead and think of it as precession, but it certainly
does not radiate energy. Note that the moment is "up", that is 54.70
relative to the field direction. Its other state, 54.70 relative to the
opposite direction ("down") is at a higher energy because it takes work
to take the "up" aligned moment and turn it to a "down" moment. Let us
say that it takes an energy E (which depends on the field strength) to
flip the moment from up to down. In an MRI what happens now is that we
shine in some electromagnetic radiation. If the radiation is of just the
right frequency, that is f=E/h, there will be a high likelihood that the
radiation will be absorbed resonantly (hence the "R" in MRI, magnetic
resonance imaging). This absorption is what is detected in MRI. This is
a very simplified overview, but it gives the basic physics principles.
The details of how the whole imaging process is very much more
complicated because of the problem of locating where the absorption is
taking place.
QUESTION:
I was wondering if it is possible you
could explain to me the basic facts of how zero point energy works. If
you could explain in most basic form please as I am not very physics or
maths orientated. I have heard it could be used as a prepulsion method.
However I cannot find anywhere an explanation i can really understand.
ANSWER:
The only meaning zero-point energy has to me is the lowest
possible total energy of a quantum mechanical system. Take, for example,
a mass hanging on a spring; classically the lowest total energy of this
system is zero corresponding to when the system is at rest. However, a
simple harmonic oscillator (which is what a mass on a spring is called)
is a classic problem in quantum mechanics because it is a system which
can be solved analytically. It turns out that it is impossible for the
mass to be exactly at rest, it must have some very small motion and the
energy of the system in its lowest energy state is called the zero-point
energy. The reason you are not aware of it in everyday life is that the
motion is so incredibly small for a macroscopic size mass on a spring
that you could never hope to observe it. On a microscopic scale,
however, it is observable. For example a diatomic molecule may be
modeled as two masses connected by a tiny spring and the lowest state is
not with the molecule at rest. Obviously, this is nothing which you
could use for propulsion.
QUESTION:
if an object is falling at a
fixed rate of 500 feet per minute, what g-force will that object
experience upon impact on the earth's surface. If possible include the
formula so other rates could be used, since I would also like to
calculate the g-force for the forward motion at different velocities.
FYI: this is an attempt at calculating the best combination of
conditions for an off-airport landing in un-inviting terrain by an
aircraft experiencing complete power loss.
QUESTION:
I fell down
the stairs two years ago and am still wondering what effect the impact
might have had on my brain. I fell head-first from the top to the
bottom, and hit the wall where it meets the small landing at the bottom
- with my head. My body kind of crumpled to my left. I fell 11 steps of
normal height, with my body turning head first, without touching the
wall or railing. The landing at the bottom is about 3 feet from the
stairs to a plaster wall. The impact was at the top of my head. Please
let me know the fall's velocity and force of impact of my head - and if
you can, how my brain would have moved inside my skull after the impact.
ANSWER:
Both of these questions are unanswerable because the force
is proportional to the acceleration, that is the time rate of change of
velocity. So knowing the velocity when an object hits and the fact that
it is at rest afterward gives you the change in velocity but you cannot
compute the rate of change of velocity without a time. So, if an object
changes its speed by 500 ft/min =2.54 m/s, its mass is 100 kg, and it
stops in 0.5 s, the average acceleration is 2.54/0.5=5.08 m/s2 and the
average force experienced is ma=100x5.08=508 N=114 lb. Since the weight
of 100 kg is about 220 lb, the force of the ground must be 114+220=334
lb. So the force you would feel is larger than your weight by
334/220=1.5, so you would feel a 1.5 g-force. This is an example, but if
either of these questioners really wants an answer, more data are
needed.
QUESTION:
While working out I was lifting dumbbells and
had the following question...what percent of the work is gravity doing
when I curl a 20kg dumbbell? For a specific example, here are some
numbers that may help…say I have a 20kg dumbbell and I’m doing curls
with one hand. It takes me 5 seconds to raise the dumbbell and 5 seconds
to lower it. My arm is about 35 cm from the elbow to the hand and my
elbow remains stationary during the curl. When I lower the dumbbell it
is much easier, so gravity must be doing some of the work, right? So
what percentage of the work is gravity doing while LOWERING the dumbbell
in relation to the amount of work it takes me to RAISE the dumbbell? For
example, if it takes me 10 Joules of work to curl the dumbbell and it
takes me 5 Joules lower the dumbbell, then is gravity doing 50% of the
work when I lower the dumbbell?
ANSWER:
Assume that the
dumbbell is at rest at the bottom, then the top, then the bottom. The
work that gravity does on the way up is 20x9.8x(-0.35)=-68.6 J; work is
negative because the weight (20x9.8 N) is a force down and the vertical
distance (0.35 m) is up. The total work done is zero and so the work you
do must be 68.6 J. On the way down it is just the opposite, you doing
negative work and the weight doing positive work. The total work that
you do is zero as is the work done by gravity. Does this mean you have
gotten nothing from the exercise? Of course not. It is just that asking
what the work done on the dumbbell is is the wrong question. You should
ask a more biological question like how much energy is required by your
body to do this exercise. If you lift it very quickly you will still do
the same amount of work on the dumbbell, but it will require less energy
expenditure from your body than lifting it slowly.
QUESTION:
What
would happen to an object if it suddenly became immune to gravit (silly
thoiught that idea is)? Oddly it would depend what time of day it is.
Assuming it's midnight when this immunitry strikes (ie it is on the
outside of the earth's orbit) it would continue on a tangent to the
orbit of the earth while the earth continues around the sun. I have
worked out that the Earth veers away from that tangential line by over
4,000 km an hour. Is this right? If so the gravity iummune object would
leave the earth's surface with a huge acceleration. (If it was midday
when immunitry struck the object would suddenly appear to weigh a vast
amount more). I realise that gravity is simple the result of objects
following curved space, is not really a 'force' and so cannot have a
anti-force (other than curving space the other way?!) and that all
anti-gravuty devices are simply using magnetic or electrostatic forces.
But this question has bugged me since reading a book calles The Seach
for Zero Point.
ANSWER:
Here is the problem with trying to
answer your
QUESTION:
for an object to be "immune" to gravity, it would
have to have zero gravitational mass. But for it to behave as you
expect, moving in a straight line with the constant speed it had at the
instant of its immunity, it must obey Newton's first law which applies
only to objects which have inertial mass. However, inertial and
gravitational mass are the same thing (a long-held experimental fact and
a cornerstone of general relativity theory). So, I am afraid that your
question would fall into the same category as questions like "suppose we
could go faster than the speed of light"; it is "suppose an object had
inertial but not gravitational mass", an unphysical situation.
QUESTION:
Is there a way of determining how temperature affects
diffusion. For example, say I have a jar filled with a foul odor and
want to lower the temperature to the point that none of the odor
diffuses through the molecular pores in the jar. Is there an equation or
method for determining what the required temperature would need to be?
ANSWER:
This is a quite technical question. In order to calculate
diffusion rate you must know the diffusion constant. The temperature
dependence of the diffusion constant is given in Wikepedia and is an
exponential function. You can then put this result into the diffusion
equation and solve. As you can see, this is a complicated problem.
QUESTION:
I understand Bohr's idea about quantum amounts of energy
and that a photon is emitted (or absorbed) when a electron changes
energy states. And I have read several times that this idea explained
the spectral lines of a hydorgen atom. But what I have not been able to
find (and has caused me to bother you with this question) is how this
expains the exact wavelength produced. Related, can you direct me to
something that explains how the speed and/or frequency of an electron
that is emitting electromagnetic wave relates to the wavelength of the
light produced. Math equation on this last one is fine... I am sure the
info is "out there" and/or in one of my texts, but I can't find it.
Hints or help would be appreciated.
ANSWER:
The key is to
understand the relationship between the energy (E) of a photon and its
frequency (f). The photon is the quantum of light emitted when a
transition occurs. This is the famous relationship Einstein discovered
in his theory of the photo electric effect, E=hf where h is Planck's
constant, h=6.62×10-34 m2kg/s. Hence, if an atom makes a transition from
a state with energy E1 to a state with energy E2, the frequency of the
emitted radiation is f=(E1-E2)/h. Then the wavelength (l) is just l=c/f
where c is the speed of light.
There is no well-defined energy of the
electron while it is emitting the photon, so your second question has no
answer. Anyhow, it is probably not a good idea to take the idea of an
electron crusing around in a well-defined orbit too seriously.
QUESTION:
In the Movie "The Core" They travel to the center of the
Earth. Now if you were down there wouldnt gravity not effect you as
much, or what because almost half of the earth is above you?
ANSWER:
The gravitational force is only caused by mass not outside
you. Therefore if you go down to half the radius of the earth your
weight will only be ⅛ of what it is at the surface. If you get to the
center your weight will be zero. You might be interested in an answer to
an earlier question.
QUESTION:
If you started with a lightbulb.
Surrounded the lightbulb with a perfect glass sphere, which was coated
on the inside, with a first-surface reflective mirror. Removed the air
from inside creating a vacuum within... and turned the light on, then
off... In theory, would the light inside the sphere bounce around within
the sphere indefinitely?
ANSWER:
I have previously answered this
question.
PS there is no such thing as a perfect vacuum either.
QUESTION:
Okay, let's say that the wind is blowing at a constant
velocity of 30 km/hr from the south. If a person were travelling at the
same constant velocity, would that person feel wind? Since the air
around the person is moving exactly as fast as the person is, would it
be safe to say it would be the equivalent of someone standing still when
there is no wind outside?
ANSWER:
You are correct, you would be
at rest relative to the air and therefore would feel no wind. An example
of this is a hot air balloon or a helium filled balloon. One of the
problems with using such vehicles to move around is that they can't be
steered, they are totally at the mercy of the winds and go where they
are blown. An airplane can only steer because of the air moving past its
surfaces.
QUESTION:
If there were a civilization on a planet
orbiting Alpha Centauri 4.37 light years away, how big would the
diameter of their radio telescope have to be to clearly receive a TV
signal from Earth? I asked the people at SETI the same question once and
never got an answer.
ANSWER:
OK, I will take a stab at this.
But, I am not an engineer and do not really know for sure how much
information one must receive to be able to put together a tv picture. I
will assume that, since the wave nature of the radio waves carries the
information, we will need at least one million photons per cycle of the
wave. My thinking is more in line with AM radio waves where there is one
constant frequency of carrier waves and the information is carried by
the amplitude of the wave; I realize that this is not really what tv is
but it should give an order of magnitude estimate. The typical power of
a tv station is about 100 kW=105 J/s. The energy of a single photon is
hf=6.6x10-34x108=6.6x10-26 J/photon so for our power source we have
N=105/6.6x10-26=1.5x1030 photons per second. The frequency of a tv
station is about 100 MHz= 108 s-1. To get 106 photons per cycle we
therefore need 106x108=1014 photons per second. 4.7 ly=4.4x1016 m so the
intensity (in photons/second/square meter) at Alpha Centauri will be
about 1.5x1030/[4p(4.4x1016)2]=6x10-5 photons/s/m2. We therefore need an
area of 1014/6x10-5=1.7x1018 m2. That is about an 800,000 mile square.
This hinges mainly on my assumption of needing 106 photons per cycle of
the wave which might be wrong by several orders of magnitude.
QUESTION:
Can beef melt? This will help me settle a long-standing
debate with a coworker.
ANSWER:
There is no definitive answer to
this question because beef is not a homogenous substance like iron or
water or salt or oxygen or whatever. It is a mélange of many different
things. It has lots of water in it and we wouldn't argue that water can
melt; thaw a frozen steak and the ice in the steak melts and becomes
water. It has fat and we wouldn't argue that fat melts; put it on a fire
and watch the melted fat drip onto the coals. But it also has lots of
organic molecules which, when heated, change their molecular identity,
that is heat causes a chemical change rather than a phase change (which
is what melting or evaporating are). When you cook something, that is
what you do—cause the food to undergo a change into something different
from the uncooked food. So regardless of which side of this argument you
are on, you both win and lose!
QUESTION:
an arrow is shot up from
the ground at 30 m/s one second later, another arrow is shot up from the
ground at 40m/s what is their displacement from the ground when they
collide? (This was the most difficult question on a test that i had 2
days ago. The top 5 students of the class all got different answers. My
answer was around 170, i don't remember exactly, i just want to know the
answer.)
ANSWER:
I only need the kinematic equations
y=y0+v0t-˝gt2 and v=v0-gt and I use g≈10 m/s2 for calculational ease.
First, find out where the first arrow is and how fast it is going after
1 s. y(1)=30x1-5x12=25 m and v(1)=30-10x1=20 m/s; the purpose of this
step is to find the initial conditions for arrow #1 to use in the next
step of the problem. Now write the y equations, choosing t=0 when the
second arrow is shot, for each arrow. y2=40t-5t2 and y1=25+20t-5t2 (we
don't need the v equations since we are not asked for any speeds). Now
set y1=y2 and solve for t and find t=1.25 s. Put this t into either y
equation and find y=42.2 m. You could go on and write the v equations to
find out the velocity of each when they collide. v1(1.25)=20-10x1.25=7.5
m/s and v2=40-10x1.25=27.5 m/s.
QUESTION:
Take a look at this
website: http://web.jjay.cuny.edu/~acarpi/NSC/3-atoms.htm It's from CUNY
so they are not exactly cranks. Note in the 3d paragraph they say
centrifugal force keeps the electron from coming into contact with the
nucleus. Is the CUNY website wrong?
ANSWER:
This is atrociously
poorly written! Believe me, centrifugal force is not a real force. In
even the most elementary physics course we learn that a force
perpendicular to the velocity (as in an orbiting particle) causes the
direction, not the speed, to change. Hence there is no reason to ask the
ridiculous question of what "keeps the two particles from coming into
contact with each other" since the orbiting particle just orbits. Let me
try to clarify what centrifugal force is. As I have alluded to above, we
easily calculate a circular orbit for a particular force and velocity
using Newton's second law, F=ma, where F is the electrostatic attraction
to the nucleus, m is the electron mass, and a is the acceleration where
a=v2/r for circular motion and r is the orbit radius. Now, suppose that
you are standing on the electron; how do you describe the situation?
Well, Newton's laws are not true in an accelerating system which is the
case here. And it is really obvious that they are not valid because
there is only one force and yet, if you are in the electron's frame of
reference, no acceleration. But suppose that you insist on using
Newton's laws to describe your motion; the only way you can do that is
to invent fictious forces to make things work out. In the case we are
discussing the electron is not accelerating and there is one real force
pointing toward the nucleus of some magnitude F (this is referred to as
the centripetal force, center seeking if you know your Latin); but the
sum of all forces must be zero and so you must postulate the existence
of a force which has magnitude F and points away from the nucleus
(centrifugal force, center fleeing if you know your Latin). That is not
really there but it is often very much to our advantage to force
Newton's laws to be true in accelerating (so called noninertial frames
of reference) for computational reasons. Let me give you a couple of
other examples of fictious forces.
Suppose you slam your foot on the
accelerator of your car. You feel a force pushing you back in your seat,
right? There is no such force; the only force on you is the seat back
pushing you forward and since you would like to use Newton's first law
your brain perceives there to be a force pushing you back.What force
makes weather patterns circulate? Because we are on a rotating earth
there is a fictious force called the coriolis force. Long-range
artillery gunners have to correct for this "force".I can't imagine what
course the CUNY page was supposed to serve, but probably a physics for
artists kind of course where the students were assumed to be incapable
of understanding Newton's laws or what acceleration is. My own feeling
is that anybody can understand these if motivated.
QUESTION:
What
is the correct equation for momentum in Newtonian physics? I thought it
was mass X acceleration. (And I've never understood why it would be mass
X acceleration.) It seems to me it should be mass X velocity. When I
looked up momentum on Wikipedia, it gave the equation: mass X velocity.
(Which makes sense to me.) But I could swear when I was in college the
equation for momentum was mass X acceleration. On the other hand, I
didn't do so well in college physics, so maybe I'm remembering it wrong.
ANSWER:
You are right, it is p=mv. The reason that ma sticks in
your head is that Newton's second law may be written F=ma. There is
another connection: since a is the time rate of change of v, dv/dt (do
you know calculus?), Newton's second law may be written F=dp/dt, that
is, force is the time rate of change of momentum. This is how Newton
originally expressed it and is the way you must express it in special
relativity, that is F=ma is not true in special relativity. In special
relativity, though, momentum must be redefined to be p=mv/√(1-(v2/c2))
where c is the speed of light. Note that when v<<c, p≈mv.
QUESTION:
I don't know very much about how light works. And for some reason this
idea just came to me. if there was a video camera that took the video
with an extremly high frame-rate would some of the frames be blacked
out, or would there be some picture missing from it because there wasn't
any light in it at the time? So is it possible that light could travel
in waves of particles, much like this: ))))) So everything we see is
actually like a series of pictures with a rediculesly high frame-rate? (
. the dots are pictures the video camera takes and, ) brackets waves of
light particles and the image that comes with it) could the camera take
pictures between the waves. like this: ).).).).)?
ANSWER:
Light
may be thought of either as a wave or as a stream of particles (called
photons). However, it would not be possible to take light which you
would otherwise send into a camera and make a shutter speed high enough
to let through zero photons; there are simply too high a density of
photons in a visible beam of light. However, if you had a very low
intensity light ray, you could arrange it so sometimes the shutter would
let through only one photon, sometimes none. So each frame would have
zero or one little dots on it. If you ran the movie you made at say two
frames per second you would see individual flashes as the photons hit
the film; if you ran it at real time the frames would be too close
together for you to perceive anything but the totality of all the
photons, the image of the original object.
QUESTION:
A friend of
mine who is an electrical engineer told me that a prof once told him
electrons don't actually orbit the nucleus of the atom. Is this true? My
friend says there is experimental evidence that sometimes the electron
goes right through the nucleus. We were drinking beer when he told me
this, so is this just BS or is there some truth to it? Lastly, assuming
electrons really do orbit the electron, I believe they move very fast.
Do they move fast enough to gain mass due to relativity? Also I assume
the weak nuclear force has to be pretty strong to keep the electrons
from flying away due to centrifugal force. On the other hand, even a
weak battery can make electrons flow in an electrical current. So how
can the electrons withstand centrifugal force as they orbit the nucleus
and yet move so easily in the flow of electricity?
ANSWER:
Part
of your question has been answered earlier. It is a useful but
inaccurate picture to imagine electrons in little planetary orbits
around the nucleus. When scales get as small as atomic distances the
identity of a particle becomes inaccurate and we should think of
particles as being represented by probablility distributions, that is a
mathematical distribution that allows you to predict the probability of
finding the "particle" in some particular small volume. Therefore it is
more accurate to visualize an electron as being a cloud in the atom, the
cloud being more dense where the particle is more likely to be. This
probability distribution extends right into the nucleus and therefore
there is a nonzero (but still very small) probability of finding the
electron inside the nucleus so, indeed, the electrons do sometimes pass
through the nucleus.
Electrons move very fast, but relativity is
only a minor correction. Anyway, I have argued that you shouldn't think
of mass increasing with speed.
The final question is completely
different from the others. A solid is bound together by the clouds of
adjacent atoms interacting and forming bonds. In some materials, which
we call conductors like copper, silver, etc., the outer electrons become
essentially free to move around in the material; in fact these electrons
behave pretty much like a gas inside the solid. When a "weak" battery is
connected across such a material, it is like a fan in a gas and it
causes the electrons to drift in the direction from negative to
positive.
QUESTION:
How do you go from the fully relativistic
form for Kinetic Energy, to the more well known ke=1/2mv2?
ANSWER:
This is a standard derivation which can be found in nearly any textbook
which covers special relativity. The trick is to do a binomial expansion
of the square root:
KE=m0c2[(1-b2)-1/2-1]≈m0c2[1-(-˝)b2+…-1]≈˝m0v2
where b=v/c and c is the speed of light. I have used (1+x)n≈1+nx+… for
small x.
I hope this was not a homework problem since I don't like
that and you would have cheated!
QUESTION:
Is there any
relationship between a sine wave and the bell shaped curve used in
statistics? They look similar. Is there a reason for this or is it just
a coincidence? I suppose a mathematician could come up with a formula to
describe the relationship. However, would such a formula have any
significance? (It just occurred to me I'm asking the same question
twice. If such a formula lacks significance that implies any
relationship between the two curves is just coincidence.)
ANSWER:
You have been looking over too restricted range if you think that a
bell-shaped curve and a sinesoidal function have similar shapes. To the
left is a comparison between the two. Once you get away from the central
maximum of the bell-shaped curve there is no relationship between the
two. There is no mathematical relationship between the two functions
however you could make a bell-shaped curve by adding an infinite number
of sinesoidal curves with appropriate weights; this is called a fourier
transform representation of a gaussian function (another name for a
bell-shaped curve).
QUESTION:
There is a lot of
"missing mass" in the Universe. Galaxies furthest away from us are
receeding at close to light speed (~c) -- and we are receeding from them
(relatively) at ~c. When objects move at close to c their mass
increases. Could galaxies receeding from each other (relatively) at ~c
be gaining extra mass that accounts for the "missing mass" in the
Universe?
ANSWER:
First, I always have told students to not take
too seriously the often stated claim that mass increases with velocity;
see the answer to an earlier question to see my viewpoint on mass. I had
a long discussion with a friend who is an astronomer quite well versed
in the theory of general relativity. He argues that this could not
possibly explain dark matter for a number of rather esoteric and complex
reasons which are beyond the scope of this site. However, there is one
simple example which should put the matter to rest: in our own galaxy
where no objects have speeds anywhere near approaching the speed of
light relative to earth, there is a severe dark matter problem. The
orbital velocities of stars around the center of our galaxy cannot be
understood in terms of observable mass in the galaxy; the similar
motions of other galaxies as well as our own are the best evidence that
we do not understand something about celestial mechanics and the
postulation of a mysterious dark matter is one hypothesis to explain
these problems.
QUESTION:
is there pure concussive effect of an
explosion in a vacuum
ANSWER:
I am not sure what you are asking.
However, concussive means the ability to shake or agitate and in the
case of an explosion would mean the propogation of a pressure pulse and,
of course, that cannot happen in a vacuum. When you see a space movie
and there is the explosion of a Klingon starship, you would not really
be able to hear it even though all space movie directors seem to think
you could.
QUESTION:
Would it be possible, with respect to
efficiency, to build a minature electrical generator to attach to an
axle of a car, transfer the electrical energy generated by the rotating
of the axle to a rechargeable battery? This would be done in order to
transfer the stored energy to your home when your car is parked in your
garage. If you had a system set up where you had a plug that you could
connect from your rechargeable batteries in the car to the input of
electricty to your house? This question has been on my mind since I read
about using wind and or hydroelectic power to cut down on your energy
bills.
ANSWER:
This is essentially how the electrical system of
your car already works, that is your alternator recharges your battery
so you can always start up your car (or listen to the radio when the car
is not running). If you put a generator on your car you can't turn it
for free, that is you must supply the energy which you are storing in
batteries and so your gas mileage will plummet. Furthermore, if you are
going to carry enough batteries to make a serious dent in your household
needs, the large weight of these will also cut down your mileage. Since
electricity is relatively cheap and gasoline is relatively expensive,
this idea is not a viable one. You may be interested in an alternative
which is one of the ways hybrid cars work: if you connect your generator
to your wheel only when you want to brake, then the kinetic energy of
your car will be converted into electrical energy instead of into heat
which is what conventional brakes do. This energy from braking is used
to charge up the batteries used to run the car in its electric mode.
QUESTION:
i really need help with prooving/finding something. I have
no idea how to do it and everyone i ask has the same problem, but i
think it can even be done without calculus. The question goes as
follows: If i have a box on a surface with coefficient of friction= mu
(not given) and i pull the box with a force T at theta degrees above
horizontal, find as a function, at which angle will i MAXimise the
acceleration for any value of mu? (as a function?). So naturally my
first step was to realized what they wanted and i got: T(cos[theta]) -
({mu}[mg - Tsin{theta}]) = ma (where m= mass, a = acceleration etc..)
Now i have tryed rearanging it, finding inequalities and many more
things but i just cant find it!! I really dont know how to do it and i
would be so happy if you could show me!
ANSWER:
I don't know how
to solve this without calculus, but it could probably be done if you
were clever. Your equation is correct, Tcosq -mmg+mTsinq=ma. If you
solve for a and then differentiate a with respect to q and set the
result equal to zero you will find: tanq=m.
QUESTION:
I have
learned that we all will inhale (at least once in our lives) the very
same atoms as our ancestors from thousands of years ago. If this is
true, does this mean that our bodies atoms are bound to this Earth and
remain here permanently after we die. Does our atmosphere and (or)
gravity restrict our atoms (after death) to the Earth, or can our atoms
find their way off the Earth into space and possibly to other worlds? I
ask these questions for spiritual reasons and out of true scientific
curiosity.
ANSWER:
Suppose that we assume that the atmosphere
gets completely mixed up by weather patterns after a relatively short
time, say a year; this essentially means that a molecule here today is
equally likely to be anywhere else in the world in a year. Now, I
calculated the volume of the atmosphere assuming it to be 20 km thick;
that would include most of the molecules. Now, I assumed a typical human
breath is about 1 liter; then I find that the number of lungs full of
air there are in the atmosphere is roughly 1.5x1021. Next I roughly
estimate the number molecules in one lung full of air to be about
3x1022. So, if I take one breath and redistribute the air over the whole
atmosphere, I will find about 20 molecules of that air in any other
breath. So, very roughly speaking, each breath you take will have 20
molecules of the last breath John Kennedy took before he died. But, we
might more likely be interested in the number of molecules over a
lifetime; taking Leonardo da Vinci, who lived to age 67 as an example,
the number of breaths breathed in his lifetime was about 7x108 (I
assumed about 20 breaths/minute), so every breath you take will contain
about 1.4x1010 molecules (that is about 14 billion) that were breathed
by da Vinci! Keep in mind that my calculations are very rough but they
should give a good approximation of orders of magnitude.
Your second
question is not really related. Gravity does a good job of keeping most
molecules in the atmosphere confined to this world. However, there are
virtually no hydrogen molecules or helium atoms in the atmosphere
because they have escaped into space. Helium is recovered as a byproduct
of natural gas, having been confined underground where it cannot escape.
The reason for this is that temperature is a measure of the average
kinetic energy of the molecules and lighter molecules have much higher
speeds than say oxygen or nitrogen at the same temperature. The speeds
are large enough that the fastest have a velocity larger than the escape
velocity and fly off into space. For the same reason, the moon has no
atmosphere because the escape velocity is much lower and all the gas
escapes.
QUESTION:
I've been wondering for a while about the
effects of fusion on gravity. Fusion is a process by which lighter
elements join to make heavier elements, releasing large amounts of
energy at the expense of small amounts of matter. However, concentration
of large amounts of matter defines gravity as a curvature of space. If
matter is lost due to fusion, does the gravity which that matter
represented go away too? Is it redistributed somehow?
ANSWER:
Let's imagine a universe with no mass, just photons. Then I believe that
spacetime would be flat. So, when mass gets smaller spacetime gets less
curved. Realize, however, that the fractional change of mass in a star
over its lifetime never really approaches a large fraction. You should
not think of gravity as being something which is conserved (as implied
by your question "Is it redistributed somehow?"). If there is one mass
there is a gravitational field; if it is made to go away (conserving
energy), the gravity goes away too.
QUESTION:
I don't know if
this is a silly question or not, but I can't find it in your old answers
(at least, not in a form that I understand). There is a lot of "dark
matter" in the Universe; and mass increases as matter moves nearer the
speed of light; the galaxies are moving away from each other at the
speed of light. Therefore, doesn't the mass of the galaxies increase
enormously as they are moving away from each other? Couldn't this
account for the missing mass of the "dark matter"?
ANSWER:
For
starters, dark matter is hypothetical and has never been directly
observed. The universe is expanding but the speed of the most distant
objects is not the speed of light, in fact not really close to the speed
of light even though they are moving rapidly, just not that rapidly.
"CORRECTED" ANSWER:
I talked with an astronomer friend and found out
that in fact the most distant objects are moving with a speed quite
close to the speed of light (about 95%). Nevertheless, this cannot be
the answer to the dark matter puzzle for reasons explained in a similar
answer above.
QUESTION:
A metal spoon and a wood spoon have been
in boiling soup for a long while. If I take out both spoons, the metal
one will feel hotter. Does the metal spoon in fact have a greater
temperature or is it just a better conductor? I guess my real question
is how can this guy be holding a white hot space shuttle tile in his
bare hand that is 1260 degrees C? Can two objects have equal temperature
where one burns you yet the other does not?
http://upload.wikimedia.org/wikipedia/en/thumb/5/5b/TPScube.jpg/300px-TPScube.jpg
ANSWER:
It is because the metal is a better conductor. They
both have the same temperature (assuming that they were both submerged).
This is why you never see fire walkers walk on red-hot metal surfaces.
The reason the man can hold the hot shuttle tile is because it has been
heated up locally so that it is hot where it was heated up but not hot
where he is touching it; this is because the tile is a very poor
conductor of heat. In the spoon example maybe I misunderstood what you
meant. If the two spoons are in the soup with their handles sticking
out, the metal handle is hotter the metal is a better conductor.
QUESTION:
;
The reason for this email it’s because I have a question
about the ocean tides here on earth. I understand that gravity bends
time/space based on Albert Einstein’s theory. My question is: Do the
ocean tides follow the path of the space bent due to the presence of the
moon? I'm working on a presentation and I wanted to talk about this
subject and at the same time give a graphical representation of this
phenomenon. For some reason I keep thinking that this phenomenon can be
explain showing the fabric of space being bent by the two bodies (Earth
and Moon) resulting on the ocean tides in other words, the earth will
look oval due to the ocean waters. The small deformation of space due to
the moon's presence will create an oval looking basket on earth's space
forcing the waters to fallow this shape depending on the moon's
position. It’s this some what correct?
ANSWER:
Suppose the
oceans were full of molasses; the tides would be much smaller, probably
not perceptable at all. And yet, the curvature of spacetime would be the
same. It is therefore fallacious to assume that the shape of the ocean
reflects the shape of spacetime. Curvature of spacetime is best
visualized by observing the bending of light by strong gravitational
fields. Research this and "gravitational lensing" for your presentation.
QUESTION:
Who was most responsible for the Grand Unification Theory?
ANSWER:
There is no single GUT. Read the Wikepedia entry on GUTs.
QUESTION:
why does fire burn up? I mean if you point a match down
the falme still goes up, why doesn't gravity draw the fire to the ground
rather than the sky?
ANSWER:
I have previously answered this
question.
QUESTION:
My question relates to how icebergs reflect
the heat of the sun back out of the atmosphere. I know that white
reflects light, but does it also reflect heat? This is mysterious to me.
What about a mirror? If the sun shines on a mirror, does the mirror
effectively redirect the light and the heat? If, in a dark room, I blow
hot air onto a white block of ice, will it reflect away? Are the sun's
light and heat one radiation or two?
ANSWER:
When we talk about
heat we are talking about energy transfer and that can be accomplished
in several ways thermodynamically. Heat energy from the sun is simply
the infrared portion of the electromagnetic spectrum which is comprised
of light with wavelengths somewhat larger than can be seen by the eye.
When this heat hits a reflective surface it is reflected much the same a
visible light. Blowing hot air, however, is a very different kind of
heat transfer; this is basically forced convection where you move a
volume of hot air to replace a nearby volume of cooler air. It is
essentially meaningless to talk about reflection of this kind of heat
transfer. There are other ways to transfer heat, the most important of
which is conduction; for example, sticking an iron rod into a fire and
waiting until your hand gets burnt.
QUESTION:
The situation is a
ball attached to a string like a swing. Apparently, no work is done on
the string, but surely the weight of the ball has a component that is in
the same direction of the motion of the ball, so some work is done on
the string.
ANSWER:
In the case of a simple pendulum the ball is
considered to be a point mass and the string to be massless. If the
string is massless you cannot do work on it because it can acquire
neither kinetic nor potential energy. If, however, the string has mass,
work will be done on it by the ball and by its own weight. In fact, if
the string has mass you don't even need a ball at the end. This is
called a physical pendulum, one consisting of things other than point
masses and massless pieces.
QUESTION:
The strong nuclear force is
said to have a very short range, owing to the short lifetime of its
carrier particle (at least as I was taught in high school many years
ago). This rang is said to determine the maximum size of an atomic
nucleus, hence this is why Uranium is the heaviest naturally occuring
element; any larger a nucleus and the electromagnetic force would start
to take over and the nucleus would fall apart. My question is: the above
make sense only if the strong force originates from the centre of the
nucleus, but it has always been explained to me as though all nucleons
(even the ones on the edge) can experience the strong force (the classic
demonstration involves magnets coverred with velcro to show how the
replusion is overcome if you get close enough). So where does the strong
force really come from and why do the outer nucleons 'feel' it to a
lesser degree?
ANSWER:
It is an oversimplification to say that
nucleus becomes unstable because of the Coulomb force becoming dominant
over the nuclear force. And, it is incorrect to simply say that in a
large nucleus the outer nucleons are "out of range" of the nuclear
force. The nuclear force is the force between individual nucleons and so
each nucleon interacts only with its nearest neighbors due to the short
range of the force. The nucleons on the surface see only neighbors
inside the nucleus and so they are bound to the nucleus as a whole.
Those on the inside see essentially no force since each sees just as
many neighbors in one direction as the opposite direction and all forces
approximately cancel out. In fact the simple model that the nucleus is
an impenetrable sphere (particles move freely but cannot escape) does a
remarkably good job describing nuclear structure as long as you include
the nuclear spin-orbit force which I will not go into here.
QUESTION:
Does the acceleration due to gravity change between day
and night? During the day, the sun would pull us toward it thus lowering
the earth's pull. At night, it would add to the the earth's pull,
increasing gravity. Is this reasonable?
ANSWER:
The answer is
yes, but the effect is very small, probably not measurable. I calculate
the acceleration due to gravity at the earth's orbit due to the sun to
be about 6x10-3 m/s2. Assuming that g=9.8 m/s2, the two values would be
9.806 and 9.794 at the equator, less than 0.1%. This is small compared
to variations in g due to the nonsphericity of the earth, local mass
variations, the rotational motion of the earth and other effects.
QUESTION:
I am reading Roger penrose's The Emperor's New Mind, and
on page 301 he says that when two slits are open the intensity at the
brightest part of the screen is 4 times what it was before, rather than
twice, as common sense would predict. I took that to mean that photons
which are subject to positive interference carry more energy than before
they passed thru the slits.
ANSWER:
I have previously answered
a similar question.
QUESTION:
Regarding radiolysis, I have read
about it in textbooks, but I still have the following questions: If the
body is 80% water, doesn't radiolysis happen alot in diagnositc
radilogy? If yes, why is this not a big concern-or is it?
ANSWER:
Radiation can be used to dissociate water. However, the probabilities
are very small. A number that I could find to give an example is that
only about 20 molecules dissociate for every 100 electron volts of
radiation energy deposited. The energy of a typical xray is like 1000
electron volts so if completely absorbed could result in 200 destroyed
atoms. And, of course, most xrays are not absorbed. Even if a million of
them were, 200,000,000 is a tiny number compared to the number of water
molecules in a thimble full of water.
QUESTION:
I'm sorry to
bother you but this is something that has been bothering me for a while
and I'd really appreciate your help. In Feynman's book on QED he cites
that the probability that an electron will couple with a photon squared
is 1/137 (or aprox. .085). He goes on to say that the proton has a
'magnetic moment' of 2.79. Now I assume that these two things are the
same, the probability of and electron/photon coupling and the 'magnetic
moment', since electromagnetic force is carried by photons. Therefore I
would expect the 'at rest charge' of one proton would be greater than
that of one electron in proportion to their coupling amplitudes; because
in Feynman diagrams it is said that the reason particles of like charge
repel each other is because they exchange a photon and the photon
momentum knocks them away from each other; like billard balls. However,
when I watched an online lecture from MIT on electricity and magnetism,
the professor stated that the force between two repulsive electrons and
two repulsive protons was aproximately the same. This is my point of
confusion. Why are they the same?
ANSWER:
You have several very
different things jumbled up here.
First the 1/137 number is called
the fine structure constant and is the number which is used to
characterize the strength of the electromagnetic interaction. It is a
particular combination of physical constants like electron charge, speed
of light, Planck's constant, etc.; see the Wikepedia entry for fine
structure constant to get the exact definition.The magnetic moment of
the proton has nothing to do with the fine structure constant. Most
elementary particles look like tiny bar magnets and the magnetic moment
is simply an experimental measurement of the strength of that magnet. It
is dependent on the structure of that particle and reflects what the
density of electric currents is. A simple (overly simple) model would be
that a proton is a charged sphere which is rotating and the rotation of
the charge comprises a current which gives rise to a magnetic field.The
third statement, I believe, simply states that the electric charge on a
proton is of opposite sign but identical magnitude as the the charge on
an electron and has nothing to do with the magnetic moments or magnetic
forces.
QUESTION:
I don't understand Newton's Third Law. If it is
true then surely, for example, it is impossible to move your hand
through a table since the reaction will always equal the weight.
ANSWER:
Newton's third law (N3) says that if one object exerts a
force on another, the other exerts an equal and opposite force on the
one. Many students misunderstand this law as you demonstrate in your
example. Instead of talking about a hand, let us assume there is a book
on the table. Are there any forces on the book? Yes, there is its own
weight straight down (let's call that force W) and maybe the table,
which touches the book, also exerts a force on the book (let's call that
force T). Since the book is not accelerating, the total force on it must
be zero (that is Newton's first law, N1) and so T must be a force
straight up which is of the same magnitude as W. These forces are equal
and opposite because of N3, right? WRONG, WRONG, WRONG! These forces are
equal and opposite because of N1 and they have absolutely nothing to do
with N3. They cannot be a N3 pair because both are on the same body
(book) and N3 addresses forces on different bodies. So, what is the N3
(reaction) force which pairs with the force T? Since T is the force the
table exerts on the book, N3 tells us that the book exerts a force down
on the table which has the same magnitude as T. And, what is the N3
(reaction) force which pairs with the force W? Since W is the force the
earth exerts on the book, N3 tells us that the book exerts a force up on
the earth which has the same magnitude as W. That's right, the book
exerts a force on the whole earth. N3 can never cause something not to
move because the relevant forces are on different objects.
QUESTION:
In a standard Newton's Rings experiment, we place a convex lens of large
radius over an optocally plane glass plate. What will be the fringe
pattern if the optically plane glass plate is replaced is replaced by a
concave lens, such that its radius is larger than that of the convex
lens?
ANSWER:
It will still be a bullseye pattern but the
fringes will be farther apart because the air gap widens more slowly as
you go out.
QUESTION:
Why does the refractive index of a material
change with wavelangth?
ANSWER:
Basically it is because the
permittivity (e)of a material depends on the frequency of the electric
field it experiences. And the speed of light is proportional to 1/√e.
The reason the permittivity depends on frequency is that the interaction
of varying electric fields is mainly the interaction with electrons
bound to atoms. A simple model is to imagine the electrons bound by tiny
springs to atoms. This then becomes the driven damped oscillator model
and the response depends on how close the frequency is to the natural
frequency of the electron on the spring (resonance).
QUESTION:
When a detector is placed at one of the slits in the double slit
experiment with light, is the wave function collapsed by the observation
of people or by the presence of the detector? (i.e. if a detector was
placed at one slit, but no one actually looked at the results would you
still get a interference pattern?) Also I am not including the actual
interference pattern in the results, only the information given by the
detector, the information of course being which hole the particle went
through,
ANSWER:
Any measuring device which determines which
slit the photon passes through will destroy the pattern, it does not
require a human to know.
QUESTION:
When the leaf has fallen a
certain distance its speed becomes constant, why?
ANSWER:
It has
to do with air friction. When an object passes through a fluid like air
it experiences a retarding force. This is how you can feel the wind, for
example. This force depends on the speed of the object; it is easy to
convince yourself of this by putting your hand out the window of a car
at low and high speeds—greater force at higher speeds. To a good
approximation, the force is proportional to the square of the speed so
something going 80 mi/hr will experience 16 times the force as something
going 20 mi/hr (which is why you should not drive too fast if you want
to conserve gasoline). A falling object is speeding up as it falls from
rest because of its weight which is a force down; but the air
resistance, which is a force up, gets bigger and bigger as it speeds up
until the force is equal to the weight of the object. Now the object
experiences zero net force so it stops accelerating. This speed is
called the terminal velocity. You can read much more detail in an
earlier answer if you like.
QUESTION:
2 bicyclists on identical
bicycles roll down a hill (starting from a stop or identical starting
speeds). One bicyclist is heavier than the other; will this person reach
the bottom of the hill faster?
ANSWER:
It depends on the
assumptions you make. I will outline the essential considerations:
If
there is no friction then they should both get to the bottom at the same
time. This is because the force down the hill on each is proportional to
the weight which is proportional to the mass so the accelerations are
the same (I am assuming you know Newton's second law).But there is
friction in the bearings of the bike, the rolling friction of the tires,
friction of the roadway, etc., but these are also approximately
proportional to the weight, so again there should be a tie.Air friction
is determined by geometry and speed, so it is not determined by weight.
The greater the speed the greater the force of air friction
(approximately proportional to the square of the speed), so eventually
an object will have a force from air friction precisely equal to but
opposite the force from gravity and it will stop accelerating; it has
reached its "terminal velocity". An object moving under the influence of
gravity and air friction experiences a greater. The terminal velocity
for the heavier person is larger, so if air friction matters (and it
does because pedaling into wind is much like going up a hill) the
heavier person will win. You can see more detail about air friction in
an earlier answer. Friction can be a complicated thing, so it would be
interesting for you to try things out experimentally.
QUESTION:
Coulombs constant 9 x10^9 can be found as 1 / (4 pi x permittivity of
free space ). It is also found as c^2 x 10 ^-7, or 1 / permittivity x
permeabilty x 10 ^-7), why is this?
ANSWER:
If you measure the
force between two point charges separated by a distance r, this force is
found to be proportional to product of the charges and inversely
proportional to r2. If you measure the charge in Coulombs and the
distance in meters, then k=9x109 Nm2/C2 as you state. This is simply an
experimentally measured number, that is the force between two charges
each 1x10-3 C and separated by 1 m would be 9000 N, a number you could
measure to get k. Suppose that you have a number N and you want to
define a new number M=2N; that is all permittivity is, a redefinition of
k, e0=1/(4pk). Your last question is most interesting. The permeability
of free space is m0=4px10-7 Ns2/C2 and, like k, it is just a
proportionality constant which tells you the magnetic force between two
current carrying wires. Now, it turns out that when you do the
mathematics you find that the equations of electricity and magnetism
(called Maxwell's equations) predict waves which have a speed of
c=[e0m0]-1/2 and this speed just happens to be the speed of light in a
vacuum. And so if you now do the simple algebra, you find that
k=10-7/[e0m0]=c2x10-7.
QUESTION:
I have heard that if one
inhabited a two-dimensional macrocosm and a three-dimensional sphere
passed through this macrocosm, then one would see a point grow into a
circle, before collapsing into a point and disappearing again. Now I
apologise for asking you about such an unscientific conjecture, but
could it be that the appearance and subsequent disappearance of
particles and atoms and so forth which has been observed by physicists
to be occurring constantly; could it be that these transient particles
are, de facto, entities from a higher cosmos passing through this
three-dimensional cosmos?
ANSWER:
You are referring to virtual
particles as you indicated in a later message. How can a particle, with
energy mc2, simply appear from nothing? The answer is that you can
violate energy conservation as long as you also obey the Heisenberg
uncertainty principle, i.e. as long as the time during which you violate
energy conservation is short enough. Quantitatively, The product ET
(energy time time) must be on the order of about Planck's constant which
is a very small number (on the order of 10=34 in SI units). So, you may
spontaneously create 1 Joule of energy as long as it does not exist
longer than 10-34 seconds. This picture has done remarkably well in
understanding virtual particles. (Incidentally, you cannot have a
virtual electron, for example, because that would violate conservation
of electric charge; instead you must have a vitrual electron-positron
pair.) Could they be understood as evidence of higher dimensions?
Scientists are loathe to say anything is not possible, but more than
simple conjecture would be needed to convince anybody—predictions of
nature are required for acceptance of a hypothesis.
QUESTION:
If
there was no wind present what force would a raindrop hit a piece of
wood, (siting on the gound) at? At what point would the force generated
by a raindrop be enough to cause damage to a piece of wood? What is the
wood was covered in a tar-like substance?
ANSWER:
A large
raindrop has a terminal velocity of about 20 mi/hr. Have you ever been
hit by a large raindrop? It does not really hurt so the force must be
pretty negligible. The force of a raindrop hitting wood will not damage
it.
QUESTION:
I've been looking at various videos on Youtube
about homompolar motors. In some videos a battery is used and in other
there is not, but in both types of set-ups... What is it that causes the
spinning action. I can some what understand the spinning when a battery
is used. In a battery set-up there is a current in the wire that makes a
magnetic field around the wire, or wires, and it is this magnetic field
that conflicts with the current in the wire causing it to be pushed
away. But in the videos that don't use a battery what is making the
whole assembly spin? I is my understanding that magnetic flux fields are
stagnant. So when a charge is applied to the "no battery" homopolar
motor is there a current traveling along the flux lines causing it to
spin? I've attached some links to clarify my
QUESTION:
http://www.youtube.com/watch?v=2hHfkK4iGBQ
http://www.youtube.com/watch?v=hXbFfMBW97A&mode=related&search=
ANSWER:
In each of your examples things get started with two wires.
These are attached to a battery which supplies the current and gets
things spinnining. A good explanation is given at
http://www.evilmadscientist.com/article.php/HomopolarMotor . After the
wires are taken away the motor continues spinning but because there is
very low friction; it is not being driven anymore. If you let it go long
enough it will eventually stop.
QUESTION:
;
I think no object can
travel any faster than whatever the force that pushes it travels. Like a
bullet from the muzzle of a gun. I assume its greatest speed in its
journey is at the muzzle of the gun. If true, and baseball pitchers
routinely pitch 100 mph baseballs, how is it possible for the pitchers
finger (s) to decelerate from 100mph in a space of what can't be more
than a fraction of an inch in a fraction of a second. Seems like that
would tough on any part of the body.
ANSWER:
Well, you should
not think of a force as being something which has a velocity; it is
simply a push or a pull. The velocity of something is maximized or
minimized as determined by the acceleration which is determined, via
Newton's second law, by the force. In your example of a bullet, the
velocity is likely greatest just as the bullet leaves the barrel because
there has been a large force acting on it and a small force acting
against it (air friction). As soon as it leaves the barrel, the only
forces on it are air friction (which slows it down in the direction it
is moving) and gravity (which accelerates it in a downward direction).
The pitcher example can be understood as follows:
The instant that
the ball leaves the hand the hand must be moving with speed 100 mi/hr
and, as you note, must experience a force to stop it.But the hand does
not stop in a fraction of an inch, it probably travels a couple of feet
or more.Understanding this you can see one of the reasons for "follow
through" in throwing balls, golf swings, etc.A rough calculation of the
force is: let the time to stop be 0.2 s, the initial velocity be 100
mi/hr=45 m/s, the mass of the hand be 1/2 lb=0.23 kg, and the distance
traveled be 1 m=3.3 ft. Then the average acceleration is 45/.2=225
m/s2=503 mi/hr/s. Then the average force is 225x0.23=52 N=12 lb. The
source of the force on the hand is the wrist. Note that the distance
does not factor into calculating the acceleration, just the change of
speed and the time. The distance and time are not independent and making
the distance larger makes the time larger which makes the acceleration
and force smaller.
QUESTION:
Is there any type of matter which cannot
be melted, even when heated?
ANSWER:
It depends on factors like
the temperature and pressure. So there is no simple answer to your
question. Many compounds will not melt for some pressure ranges but they
will sublime, that is turn into a gas directly from the solid. An
example is carbon dioxide (dry ice) which does not melt at atmospheric
pressure, but it does sublime.
QUESTION:
How far would a person
need to fall before they accelerate to their "terminal velocity." 100
feet? 500 feet? Higher? I'm told that terminal velocity is about 125 mph
for a person free falling.....and that the acceleration formula is 33
feet/second/second. But I don't know how to reverse that math.
ANSWER:
What the terminal velocity is depends on a number of things
including the skydiver's weight, the density of the air, and how he
orients himself relative to his fall. If he orients in a belly flop
position he will have a lower terminal velocity than if he falls feet
first. Also, he technically never reaches the terminal velocity but just
approaches it asymptotically. But you can estimate when he is within,
say 95% of the terminal velocity. The details of the physics are given
in a previous answer; I will just give you the results for your
situation here. Choosing the mass to be 100 kg (about 220 lb), the air
density to be 1.3 kg/m3, cross sectional area to be 1 m2 (more like the
belly flop position), and the drag coefficient 1.2, I find a terminal
velocity of about 35.4 m/s (about 79.4 mi/hr). The characteristic time
is about 3.6 s; this is the time it takes the speed to go to about 76%
of the terminal velocity. If you wait twice the characteristic time,
about 7.2 s, you will reach about 96% of the terminal velocity. The
characteristic distance is about 64 m; this is the distance it takes the
speed to go to about 63%. If you go three characteristic distances, 192
m (about 630 ft), you will reach about 95% of the terminal velocity. If
you are interested, the characteristic time is v/9.8 s and the
characteristic length is 19.6/v2 m where v is the terminal velocity in
m/s. It is interesting to note that cats that fall out of skyscrapers
usually survive because their terminal velocity is slow.
QUESTION:
;
How can motion be generalized by simply looking at an objects velocity
and acceleration. More specifically, why do we only use the first two
derivatives of distance to explain the change of distance? Why don't we
consider higher order derivatives? Wouldn't an inclusion of these higher
order derivatives be necessary to fully account for motion? The question
is "Why can we generalize changes in distance by looking only at two
derivatives of distance?"
ANSWER:
Actually, you don't really
need anything but the position as a function of time to know everything
there is to know about the motion of a particle. Once you know that,
just differentiate it to get the velocity which is the rate of change of
position. If you care to know the rate of change of velocity
(acceleration), differentiate the position twice. If you wish to know
the rate of change of acceleration (which engineers often do and call
"jerk"), differentiate the position three times. If you want to know how
the jerk changes, differentiate four times. And so forth. But every bit
of this information is contained in the position as a function of time.
Physicists are normally only interested in velocity and acceleration
because, among other things, Newton's second law (N2) says that a force
causes an acceleration. It turns out that accleration is not a useful
quantity in the theory of special relativity since N2 in the form F=ma
is actually not correct in relativity.
QUESTION:
Do electrons
maintain a standard orbit about the nucleus?
ANSWER:
Actually,
the idea of electrons being in well-defined orbits in an atom is just a
pictorial way to qualitatively understand atomic structure. Originally
Niels Bohr solved the puzzle of how atoms are constructed but his ideas
later evolved into a much more complete theory of atomic structure. An
atom consists of "clouds" of electrons around the nucleus, that is the
electron does not maintain its identity as a point particle but becomes
"smeared" over the volume in a way which is determined by the properties
of the "orbital" it is in. This is quantum physics. However, if you say
that the shape of the cloud represents the orbit, then, yes, electrons
in one atom have the same distribution as in any other atom of the same
element.
QUESTION:
Hypothetical situation: I'm walking in the
park. Then, the earth explodes, casting the fragments of earth to outer
space. Not unlike the big bang. Now, I am smack dab in the middle of one
of those fragments. What is the cause of my death? Will my tendency to
remain unmoved turn me into a meat puddle? Or will some other force
counter act that so that I die from the loss of atmosphere and loss of
oxygen (I doubt this)? From freezing (I doubt this too)? Your help is
great appreciated as to what method in which I would die, and about how
long my existence will be from explosion to death.
ANSWER:
The
fragment you are on suddenly experiences an enormous acceleration as a
result of the enormous force it experiences. It pushes outward on you to
give you the same acceleration, so it must push on you with an enormous
force, far more than your body is designed to survive. It is basically
the same as your hitting the ground with a very high speed (like after
jumping from a tall building)--the huge acceleration of your stopping
requires a force and that force kills you.
QUESTION:
If I heated
my oven to something like 500 deg F, and it was a perfect insulator,
would the temperature inside eventually decrease due to irreversible
processes such as friction between gas molecules and possible
deformation from molecular collisions?
ANSWER:
By definition a
"perfect insulator" will not let any energy out. We never talk about
friction between two atoms or molecules since it is a macroscopic
phenomenon resulting microscopically from interactions between
molecules. In this context if one molecule gains energy in a collision
the other mus lose exactly the same amount. I do not know what you mean
by deformation, but at normal temperatures the only excitation possible
is rotational excitation and this is already included in the microscopic
description of the hot gas. So, the temperature will not change.
QUESTION:
I recently read an article about "nothing" in the center
of the universe. Since the "hole" is 5 to 10 Billion light years away,
how long would it take to get there using current technology (such as
the fastest man-made object: 250,000 km/h) and in a space craft
traveling at 99% of the speed of light? Also what would be the
relativistic age difference (earth vs spacecraft observer)?
ANSWER:
(I will take the 10 billion light year distance; everything
is half as large for 5 billion light years.) The first velocity you
quote, 250,000 km/hr is about 0.00023=0.023% the speed of light, so both
observers would see the same elapsed time which would be
10x109/2.3x10-4=4.3x1013 years, about 43,000 billion years. The case of
a speed 99% the speed of light, we would see it take about 10 billion
years (just a hair longer) but the observer in the space craft would see
much less time elapse. He would see the distance to the hole to be
contracted to 10x(1-.992)1/2=1.4 billion light years; so the time it
would take him, according to his clocks, would be 1.4/.99=1.42 billion
years.
QUESTION:
An acquaintance and I are having a heated
discussion relating to the 1960 jump from 103,000 ft from a gondola by
Joe Kittinger. According to several reports, Kittinger reached speeds
over 600 MPH after he jumped. Since I can't prove that he did, I'm no
physicist, he believes he must be correct. How can I determine the
speeds that were reached in this jump?
ANSWER:
In principle,
this is a simple free fall problem. In practice, we need to worry about
air resistance since that becomes important in real life at high speeds.
However, there is very little air above about 60,000 feet, so let's
assume that there is no air resistance and see how far he has to fall to
reach a speed of 600 mi/hr and if it is less than about 40,000 feet he
probably achieved that speed. The acceleration due to gravity is about
21.8 mi/hr/s; that is a freely falling object will gain about 21.8
miles/hour as each second clicks by. One pertinent physics equation is
v=at where v is the speed (assuming we start from rest), a is the
acceleration, and t is the time. So, putting 600 in for v and 21.8 in
for a we can solve for t: t=27.5 s; in other words, after about a half a
minute the object will be going 600 mi/hr. The second pertinent equation
is s=˝at2 where s is the distance traveled in time t. Solving for s I
find s=12,000 ft, that is he will have a speed of 600 mi/hr when he is
at about 90,000 ft, still far above where there is signficant air.
(Incidentally, in the second calculation I used a=32 ft/s/s so the units
would come out right, viz. feet.) So, I would say that yes, he must have
gone at least 600 mi/hr. I did a little research and saw 714 mi/hr
quoted as the highest speed he achieved. Once he starts encountering
significant amounts of air he will begin slowing down.
FOLLOWUP
QUESTION:
This is a follow-up, and didn't know if I should post it
online or not, since you've already answered it. But, the person with
whom I'm having this discussion still insists you're answer is wrong. He
fancies himself smarter than a nuclear-physicist, I guess, and, by his
calculations , the top speed that Kittinger could have reached is 350
mph. Here is his argument and his calculations, referring to your
response.
"That's just a repeat of what the other professor said, and
in both cases they conveniently ignore drag. If you're going to ignore
drag then ignore it and the guy keeps falling at increasing speed. Why
stop accelerating at the point that corresponds to what the claims are?
When you plug the drag variables into NASA's algorithm Kittinger doesn't
get to 614mph. The professors don't bother to verify that the air is too
thin to have any effect. Tell the college professor's to go to the
Chemical Engineer's Handbook and look up Fluid and Particle Dynamics. In
there is a table that describes the activity of bodies in free fall
through a fluid. When they're going slow, they are stable. As they
increase in speed they first start to tumble erratically, then they
start spinning about their axis of least inertia. The tumbling starts
somewhere around Mach 0.4 and the spinning around Mach 0.6 That's the
flat spin the story eludes to, and the college professors ignore. If he
fell at 614mph he's at Mach 0.9 and is in a flat spin. The big problem
is all the contradictory statements that are attributed to Kittinger. He
the first supersonic skydiver. He gets to an estimated 614 mph or 714.
He has no sense of speed, yet he knows he keeps accelerating after the
drag chute opens. That chute opens at 13 secs, or 16 secs or at 96000
feet. First of all drag doesn't work like a break. A body sitting still
has no drag. As it speeds up drag increases and keeps increasing until
the force propeling the object and the force of drag are equal. Then the
object stops accelerating and moves at constant speed as long as force
and drag stay the same. Drag is related to Velocity(speed) by the drag
equation. D = 0.5 x Cp x p x A x V^2 So as long as you keep the Cp,p, &
A the same, there is one value for drag for every value of speed (V) I'm
not going into all the other crap, but the force pulling Kittinger down
and causing him to speed up is gravitiy working on his weight. At
roughly 300 lbs it takes 300 lbs of drag to stop him from accelerating.
He's the shape of a brick, roughly half as wide as long and 1/3 thick as
long. The Cp of a brick is 2.1. We use that to compute air flows through
our tunnel kilns at the brickyard. The density of the air is about
0.00004 slugs/cuft. He is exposing about 15 sqft of area to the "wind".
So if we plug in all those numbers in the Drag equation and solve for
V(speed), he stops accelerating at 690 fps or 470mph. I'd say the air is
thick enough to make a difference. But that doesn't take into account
the drag on the small parachute he deployed to keep himself from going
into that flat spin. It's 6' in diameter that's 28.26 sqft of area. The
Cp for a round chute is 1.5. So as long as the drag on the chute and the
drag on Kittinger doesn't total 300 lbs or more he is still
accelerating. At 13 secs the total drag is 254lbs and his speed is 283
mph. He'll accelerate for less than a second more and get to about 290
mph. At 16 seconds the total drag is 384 lbs, so he'll decelerate from
347 mph with a pretty good jerk. I have no idea where or why the 96000
ft comes from, so I'm going to ignore it. He supposedly used a timer to
deploy the chute. The speed of sound is around 660mph and tumbling would
start somewhere around Mach 0.4 which is 0.4 x 660 = 264mph. That's damn
close to the 13 sec mark. We'll never know based on the info available,
but I don't think he got over 300-350mph."
Here are the facts, as
presented in an article at
http://www.centennialofflight.gov/essay/Explorers_Record_Setters_and_Daredevils/Kittinger/EX31.htm
1. Kittinger jumped from 102,800 ft.
2. His weight is
approximately 300 lbs.
3. He was falling in a backward orientation
4. After falling for 13 secs, a small chute, 6 ft. in diameter,
opened.
5. He feel for 4 min. and 36 secs more bringing him to
17,500 ft.
ANSWER:
Your friend certainly makes some quite good
points, although he is maybe a bit overemotional and maybe a little
hostile to us college professors. It is true that we often simplify
problems to get to the core of a problem. So let me be a little more
careful and go over the calculation of your friend the way I would do it
since some of the numbers he quotes are undocumented and some of them
(in particular slugs/ft3) are completely incomprehensible to a modern
physicist! Your friend must be an engineer. His equation is quite
correct, that is the terminal velocity is given by v=[(2mg)/(rACp)]1/2 .
Now it is easy to see how disputes can arise because the answer, of
course, depends the choice of constants some of which are not easy to
estimate (for example, I would say approximating the man as a brick is
what some nutty college professor might do). The density of the air at
100,000 ft is about 1/100 the density at sea level and, since the
density at sea level is about 1.3 kg/m3, I will take r=1.3x10-2 kg/m3. I
searched the web for tables of drag coefficients and found that a
parachutist has Cd=1-1.4 (not 2.1 as your friend assumed); I will use
1.2. The cross sectional area also requires a rough estimate since it
depends on whether he is falling, for example, feet first or is falling
"belly flop" orientation. I will assume the latter so as to get as small
a speed as possible and I will estimate the area as about A=2 m x 0.5
m=1 m2 (your friend uses 15 ft2, about 1.4 m2). Using m=136 kg (300 lb)
and g =9.8 m/s2, we are ready to estimate v; I get v=413 m/s= 924 mi/hr.
But, there is important information which you did not tell me the
first time through--the opening of the small chute. So now the cross
sectional area is about 2.5 m2 and the drag coefficient is about 1.42 (I
model it as an open hemisphere into the wind). So now I get a reduced
terminal velocity of v=240 m/s= 537 mi/hr.
Now I have the terminal
velocities, what happens in our specific example? The space is too
limited here to put in all the details, but I have assumed a constant
density for the first 4000 m (about 12,000) of fall. I went back to an
intermediate mechanics book to find the dynamic analysis of the falling
body with quadratic velocity dependent drag force and I could apply
(knowing the terminal velocities from above) the analysis to this
specific problem. In the first 13 seconds I find that he falls about
1000 m and ends up with a speed of 130 m/s (291 mi/hr). Then, after he
has fallen 3000 m more he will have a speed of 208 m/s (465 mi/hr). But
he is still accelerating but now the air gets denser so his acceleration
decreases even more; nevertheless, as he falls, since he is still fairly
far below terminal velocity (240 m/s) he will end up going faster than
465 mi/hr.
So who is right here? Well, your friend is right in that
we will never know based on information we have. I can easily imagine
that I have made a factor of two error in the density, the area, or the
drag coefficient (and so could your friend); increasing all by a factor
of two would reduce the terminal velocity by almost 2/3 which is the
difference between 600 mi/hr and 200 mi/hr. The results are too
sensitive to modest changes in the parameters.
QUESTION:
At our
work we have gone stupid over GREEN Issues, we have been instructed to
turn off the hand dryer at the wall plug when our hands are dried, thus
saving some of the blow cycle. Now when you dry your hands you turn it
on at the plug, get the remaining part of the last cycle and then have
to turn the blower on by the big silver button on the dryer. Are we
saving enery at all or is "turning on/starting the dryer" the big user
of power? Thus it would be better for it to finish its cycle each time
ANSWER:
It is not true that turning an electric appliance on
and off uses more energy. (It is also not true that turning a car off
and back on at a long traffic light consumes more gasoline than running
the whole time.) Electric heaters like your hand dryer are among the
worst energy hogs so running them only as long as necessary to dry your
hands does make sense. However, if your employer is really serious about
energy conservation, he would uninstall the electric dryers and replace
them with paper towels or, even better, one of those machines which has
a long cloth roll which is simply washed and then reused when it is all
used up.
QUESTION:
Compressing gaseous nitrogen makes liquid
nitrogen which is very cold. But compressing things makes them hotter.
Any help alleviating my confusion will be greatly appreciated.
ANSWER:
The compressed gas does get hot, but that is not the end of
the process. Here is a link with an explanation.
QUESTION:
This
question has to do with television signals emitted from this planet. If
there is a star that is say exactly 40 light years from us, how weak
would our "electromagnetic reflection" be from the star or a planet (I'm
assuming a reflection is possible?) by the time we get it back, some 80
years after it left? I realize that probably not all stars would reflect
equally, so my question is geared toward whether there might be anything
at all that could be measured and analyzed someday.
ANSWER:
Almost anything will relfect electromagnetic radiation. The real problem
here is the intensity. The intensity of radio waves emitted from the
earth will fall off approximately like 1/r2 where r is the distance. So,
if you have a certain intensity 1,000 miles from earth, the intensity
1,000,000 miles away will be (106/103)2=1,000,000 times weaker; and
1,000,000 miles is a very small number compared to the distance to a
star. And the reflected signal will lose just about the same fraction
coming back. My guess is that the intensity would be so low that no
information could be obtained from it.
QUESTION:
If an object is
completely submerged in water (let say sitting on the bottom of a lake)
why does buoyant force help you to lift the object out of the water.
What I'm confused about is why the pressure of the water pushing down on
the object doesn't hurt you as much as help you?
ANSWER:
Let's
think of it as a box. The bottom of the box experiences a force due to
the pressure in the water which pushes up. The top of the box
experiences a force due to the pressure in the water which pushes down.
But the force on the bottom is bigger in magnitude than the force on the
top because the pressure gets bigger as you go deeper. Therefore there
is a net upward force on the box which we call the buoyant force.
QUESTION:
What is the speed of gravity?
ANSWER:
This quetion
has been previously answered.
QUESTION:
How would i calculate the
number of grains of sand on Earth ???
ANSWER:
There is, of
course, no way to calculate it. You could estimate it, however. I am not
a geologist, so I really don't know how much sand there is in the world
but it must be a lot. I will take a wild guess that there is enough sand
to cover the entire earth to a depth of 10 cm =10-1 m (there is probably
more than that). The surface area of the earth is about 5 x 1014 m2
(from A=4pR2) so the total volume of sand is about 5 x 1013 m3. Now, I
will guess that a typical grain of sand would have a diameter of maybe
0.1 mm=10-4 m so the volume of a typical grain of sand would be about
10-12 m3. So the number of grains of sand would be the ratio of the
volumes (volume of sand/volume of one unit of sand), about 5 x 1026,
quite a lot! This is comparable to about how many atoms there are in
your pencil.
QUESTION:
during the double slit experiment, i
understand the bright patches are caused by the peak of one wave
interfering with the peak of another to form a doubly high peak. but
when the bottom of two waves also interfere with each other to produce a
doubly low wave, does this also produce the bright patch?
ANSWER:
Every point on one wave interferes destructively with the corresponding
coincident point on the other wave.
QUESTION:
One of my
classmates claimed during our study group that if you glue two permanent
magnets together, north to north that eventually they will reverse
poles… is this true?
ANSWER:
What happens depends on many things
like the materials from which each magnet is made, temperature, how
strong each magnet was, etc. One thing is for certain, though: they will
not both reverse their polarities. Either neither will or one will or
both will become demagnetized.
QUESTION:
Let's say I have a metal
rod about a half an inch thick and 300,000 kilometers long. Then say I
give one end of said rod a mighty whack with a hammer, propelling it
forward by one inch in a mere fraction of a second. My questions is,
wouldn't the impact of my hammer cause the other end of the rod to move
forward one inch just as rapidly as the end where I whacked it? And
would this violate Einstein's law that states that nothing can move
faster than "C"? Or would the far end of the rod have to wait one second
after my whacking my end before moving forward by one inch?
ANSWER:
Have you thought about the implications of your question? I
figure the mass of the rod would be about 1010 kg. Suppose that you
exert a constant force such that after 0.1 s it is moving with a speed
of about 0.5 m/s; it would have moved about an inch in this time. The
force is the change in momentum divided by the elapsed time so, roughly
speaking, the required force is about 1012 N. Where are you going to get
such a force? Anyhow, to the meat of your
QUESTION:
no, the other end
would not start moving instantaneously. It could not begin moving until
at least one second later than your end started moving for the reason
you state: no information can travel faster than c. In reality, it would
be much longer than one second because your "mighty whack" will compress
the rod and this compression will move with the speed of sound in the
metal and this compression is what travels to the other end to move it.
QUESTION:
If I were to stand on the moon with my head facing
directly forward into the line of orbit, would I weigh more than if I
were standing on the exact opposite side of the sphere, in the rear so
to speak? In other words, does the movement of a planetary object either
add or subtract from one's mass depending on where they might be
situated?
ANSWER:
Your weight is the force which you experience
due to the gravitational field you are in. Assuming the moon to be a
homogenous sphere, your weight is independent of where you are on the
surface and of the motion of the moon. Your mass is the inertia you have
in your rest frame and it is independent of everything. Rest mass is an
inherent property of an objece, weight is determined solely by mass and
field.
QUESTION:
Given that gravitation and acceleration are
locally indistinguishable, and that "gravity" is causing the light to
bend in gravitational lensing, can acceleration also cause gravitational
lensing in some aspects?
ANSWER:
Suppose that you are in an
accelerating elevator with a hole drilled in the side; if a beam of
light enters parallel to the floor, you will see it follow a parabolic
trajectory as it crosses the elevator. So the answer is, yes, light
bends when observed from an accelerating frame of reference.
QUESTION:
Given initially that a Powerful large magnet and a heavy
soft iron are attached magnetically to each other , we obviously have to
expend a lot of ENERGY to separate it away from each other. But by law
of conserv. of energy and E=MC^2 ,should the soft iron(or magnet)
initially attached to magnet (or iron) weigh more? If not where is the
energy we expended? if so it is unclear where we should bring relativity
to solve it. (Same can be asked with gravitationally strong object.But
it would bring Gen.Rel into question, which would be uncomfortable for
this simple question)
ANSWER:
Yes, the magnets will be more
massive after you have separated them. But, the amount will be
unmeasurably small. Suppose that you do 100 J of work to separate them.
Then the mass increase will be Dm=100/(3x108)2 kg, about 10-15 kg!
QUESTION:
If an object weighing 500lbs (let's say an elevator) falls
from a height of 1,000ft (without any resistance other than air) and
hits the ground (concrete), how much energy would it be equal to. And if
you would, please translate into sticks of dynamite.
ANSWER:
The
energy when it hits the ground is about 680,000 J which is equivalent to
about 0.16 kg of TNT.
QUESTION:
Whats the lowest Temperature ever
attained here on earth according to latest details ?? .Some unconfirmed
source told me that it was less than a millionth degree above 0 kelvin
ANSWER:
The lowest temperature I have found reference to is 100 pK.
That is one ten billionth of a degree Kelvin.
QUESTION:
often
aluminum outboard props bend and warp, the manufactures answer is that
over trimming the engine so that it sucks air down into the props
vortex, the air becomes traped, supper heats and then warps or melts the
prop. wouldnt that trapped air have to reach 660 degrees to melt the
prop? is that even possible?
ANSWER:
The prop is not being
melted, just warped. At high temperatures metals become softer, more
easily deformed (that's why the village blacksmith had a hot fire).
QUESTION:
To our eye + brain, a material has color when it absorbs
all wavelengths of the visible spectrum and reflects 1 wavelength. For
example, a red brick has color because it absorbed visible light and
reflected light with the wavelength associated with the red color. Why
did all the other wavelengths of light get absorbed and the red light
not get absorbed? Are all wavelengths absorbed and the red color
wavelength is radiated? Does this have anything to do with the HOMO-LUMO
Gap (chemistry)?
ANSWER:
Of course, your explanation is a
little oversimplified. Nothing absorbs everything except one wavelength.
A red brick absorbs more of the light in the shorter wavelength (blue)
end of the spectrum than in the longer wavelength (red) part of the
spectrum. But your general idea is right. What gets absorbed is
determined entirely by the properties of the molecules in the material,
it is an atomic-level effect. All molecules have absorption and
radiation spectra and they vary from material to material. I have no
idea what the HOMO-LUMO gap is.
QUESTION:
Light, radio signals,
and audio are all types of waves which can be measured in Hertz. I know
that what we hear (audibly) are compressions of air created by the wave
(let's assume for this question we have an audio wave of 900Hz). Light
is also a wave, lets choose yellow which would be 515THz ( terahertz ).
Considering this, light can travel accross empty space (obviously) as a
wave. Here is where I find a problem that I want answered: If a 900HZ
wave were created from a source in space (not as sound, just a 900hz
wave) and was directed toward earth could we (on the earths surface)
detect the 900hz signal? If so how, wouldn't this cause sound
compression when it reached our atmosphere, making it audible? If not
then why, 900hz is a wave just like 515THz, is it possible to have a
900hz wave that you can't hear on the surface of the Earth with air? Or
If 900hz can not travel through space then why can a lightwave (or
whatever wave) travel through space at 515THz but a 900Hz wave cannot,
radio and lightwaves do not require the presence of air to travel
through space? Unless there is another possibility I have not thought of
above, all the options seem contrdictory to what I Understand about
physics, sounds waves, etc... I am by no means a scientist or even a
physics student, just a pondering thinker.
ANSWER:
The whole
key is "what is doing the waving". For sound, as you note, it is the
air. For electromagnetic waves (radio, light, xray, gamma ray,
microwave, etc.) it is electric and magnetic fields. You can hear
compression waves in the air but you cannot hear electric or magnetic
fields. Your eye can detect electromagnetic waves in a narrow frequency
range and we have instruments to detect other frequencies. Hence, if the
900 Hz wave came across space then it must have been electromagnetic so
you could not hear it but you could detect it with an appropriate
antenna and electronic receiver. By the way, the wavelength of such a
wave would be about 333 km.
QUESTION:
Hi I'm a 52 year old high
school teacher and this is a problem I could not solve in the new
curriculum. Here it is, word for word:
A red ball is stationary on a
billiard table OABC. It is then struck by a white ball of equal mass and
equal radius with velocity u( -2i + 11j ) where i and j are unit vectors
along OA and OC respectively. After impact the red and white balls have
velocities parallel to vectors -3i + 4j, 2i + 4j respectively. Prove
that the coefficient of restitution between the two balls is 1/2.
ANSWER:
First, allow me a little rant! It is utterly ridiculous
that this problem is part of a high school curriculum. Coefficient of
restitution (COR) is one of the least important concepts in classical
mechanics. Furthermore, it is nearly always defined in terms of a
one-dimensional collision which the collision in your problem is not, so
it looks like the problem writer is trying to confuse the reader (which
I consider to be poor educational method). Furthermore, I find that I do
not get 1/2 for the coefficient of restitution when I work the problem.
I will outline the solution to the problem and give my results. You can
reconstruct the solution and see if I have made any errors. First, the
COR e is related to the energy loss Q in the collision by Q=˝mv2(1-e2)
where m=m1m2/(m1+m2) (reduced mass) and v is the incident velocity (if
one of the two particles is at rest as it is here). It makes no
difference what the actual masses are since they are equal, so I shall
choose m1=m2=1 kg such that Q=31.25(1-e2) J. (I have used v2=125 m2/s2
as given in the problem.) Now, just calculate Q to get e. The
information given about the recoiling velocities is their directions,
not their magnitudes; to get the speeds you must do momentum
conservation. The red ball moves at an angle of 53.10 above the negative
x axis and the white ball moves at an angle of 63.40 above the positive
x axis. Conserving momentum in x and y directions I now find the speeds
of the red and white balls: vr=7.5 m/s and vw=5.59 m/s. Hence the energy
after the collision is 43.75 J and before the collision 62.5 J, so
Q=18.75 J. Solving now for COR: 18.75=31.25(1-e2), e=0.63, not ˝.
There is actually another way you can do it: if you work in the center
of mass system it essentially looks like a one-dimensional collision
since the two particles after the collision move colinearly apart with
speeds of 3.54 m/s each so that the speed of separation is 7.08 m/s and
the speed of approach before the collision is 11.18 m/s. The COR is
defined as the ratio of the speed of separation over the speed of
approach which works out to, you guessed it, e=0.63! Now I have more
confidence in my solution.
QUESTION:
what, if any, would be the
major 'noticeable' differences in the universe if the speed of light
were drastically higher, say 10x, 100x or 1000x?
ANSWER:
For
starters, you would not be here to ask this question. The existence of
life as we know is very sensitive to the values of the most important
physical constants, the speed of light, c, being one of them. The
easiest way to see dramatic effects is from good old E=mc2. If c were
10x bigger, the energy equivalent of mass would be 100 times greater, so
the energy being produced by the sun would be 100 times what it is; talk
about global warming! Assuming that protons and electrons still existed
you could still have hydrogen since atomic physics is not very affected
by relativity, but when you tried to make a nucleus you would find that
the masses of the nuclei were very much less than the sum of its
components due to the enormous binding energies. In fact, I do not think
you could have a neutron so you could make no nuclei and therefore you
would have no chemistry and the stars would not be able to make energy
using fusion.
QUESTION:
What is the basic physics behind laser
cooling.
ANSWER:
The basic physics is essentially momentum
conservation. If a ball is moving toward you and you shoot it with a bb
gun, the ball slows down (cools) a bit. Many collisions with bbs will
slow it down more. In laser cooling, the ball is an atom and the bbs are
photons from the laser. A nice simple explanation can be seen here.
QUESTION:
Given COMPLETE information about Hydrogen and Oxygen and
Using physics laws "as it is now" to its full extent (forgetting about
the mathematical and Quantum mechanical complexities) can we basically
"predict" how a combination of type H2O out of these gases behave? for
example ,"Predict" that such a material would be liquid under room temp.
and has 1Kg/cc density, etc etc.?(we can dispense with all other
branches of science and make physics "universal"
ANSWER:
When
you say to forget about "quantum mechanical complexities" you guarantee
that the answer to your question is no. However, "complete information"
really means detailed wave functions of hydrogen and oxygen atoms; given
that information, excellent predictions of the properties of H2O may be
calculated.
QUESTION:
I was wondering why increasing the distance
between the plates of a parallel plate capacitor (when it's charged and
not connected to a circuit) increased the Voltage. I realize that since
this decreases the capacitance and the charge remains the same then by
then equation Q=CV the voltage must increase. But logically this doesn't
make sense to me. Since the equation for voltage is V=kq/r, this would
imply to me that as you increased the distance between plates you'd also
be increasing the distance between charges. Thus I would think voltage
would decrease.
ANSWER:
The voltage you quote is for a point
charge, not parallel plates. For parallel plates the electric field E is
uniform and so the potential difference is V=Ed where d is the spacing
between the plates. The field is determined by the charge Q on the
plates and the area A of the plates, E=Q/(e0A) so the field stays the
same when the plates are separated.
QUESTION:
Which weighs more.
There are two identical water bottles both are filled with the same
amount of liquid water. One is then frozen. Both bottles arer taken on a
hike. The dew point is such that the frozen bottle starts to form
condensation on the outside. Will the frozen bottle endup weighing more
due to the condensation that forms on the frozen bottle ?
ANSWER:
Freezing the water will not affect its weight so both bottles will weigh
the same after one has been frozen. So, the condensation will cause the
cold water to be heavier. [A technicality: because E=mc2, the frozen
bottle, because energy has been taken from it to cool and freeze the
water, will actually be lighter. However, the amount by which it will be
lighter will be unmeasurably small, so it may be ignored. A rough
estimate: suppose that 1,000 J of energy are removed in doing the
freezing; the mass equivalent is 103 J/(3 x 108 m/s)2 which is about
10-14 kg!]
QUESTION:
This is a question that's bugged me for a
long time. If you can shine a light into a hollow perfectly smooth,
reflective sphere with no means of the light escaping that sphere - is
any sort of energy built up within?
ANSWER:
There is no such
thing as a perfectly smooth, perfectly reflective surface. If there
were, energy would build up inside the sphere.
QUESTION:
I
understand that the speed of light is a constant, ie it is always the
same in all circumstances. I have also been taught that refraction is
caused as light hits a substance, through which it can pass, at an angle
and is slowed. The lower part of the wave hitting before the upper,
relative to the surface, and slowing causing an angle in the lights
path.. So which is it, is light actually slowing when it travels through
a substance or not?
ANSWER:
The law is that the speed of light
in vacuum is the same for all observers. Light, when passing through
matter, moves slower.
QUESTION:
Real life
QUESTION:
Tire pressure
on and off the car: I am getting a new tire for my car. While it's on
the rack, they check the pressure and it's a perfect 32 psi. They put
the tire on my car, then lower the 3000 pound car back down on it, and
say see ya' later. I say,"Shouldn't you check the pressure while the
weight of the 3000 pound car is down on it?" "Nah", they say, it doesn't
change. That doesn't make sense to me. I actually asked this question to
my brother who is a ultra-high vacuum physicist at Sandia Labs, and he
didn't know. I also asked this question at the famous Cartalk.com forum
and got laughed out of it.
ANSWER:
Here is the basic physics,
the ideal gas law: PV=NRT where P is pressure, V is volume, T is
absolute temperature, N is the amount of gas, and R is a constant of
nature. Let's assume that T stays the same when the car is lowered off
the rack. Now, presumably the volume of the gas in the tire decreases a
little bit; therefore, the pressure must increase a little bit to keep
the product PV equal to the constant NRT. However, the volume changes by
a very small amount compared to the total volume of the tire, so for all
intents and purposes (but not exactly) "it doesn't change".
QUESTION:
If you consider a rock hanging from a two vertical
massless ropes with a symetrical wieght distribution, and the system is
staionary, is there anyway possible that the tension in the ropes will
be greater than or less than half the weight of the rock?
ANSWER:
It depends on where the strings are attached to the rock. If one is
directly above the center of mass, it will carry all the weight and the
other will have zero tension. If they are equal horizontal distances
from the center of mass, each will carry half the weight. The thing is
that the sum of all the torques about the center of mass must be zero.
So T1d1=T2d2 and T1+T2=W. where d is the distance of each string
horizontally from the center of mass.
QUESTION:
How does High
voltage transmission of electricity through long distances helps in
reducing the energy loss during transmission?
ANSWER:
The power
P dissipated in a resistor R is P=IV; if you increase the voltage and
keep the power the same, the current becomes small. But, in the
transmission line, if you use Ohm's law V=IR, P=I2R, so low current
means low power loss.
QUESTION:
By the phrase "High Tension
wires" what should we asssociate the meaning for "Tension"? Frequency
(Hz) ? Volts ? Current strength? (Amps)?
ANSWER:
The voltage is
high. The current is low. The frequency is 60 Hz.
QUESTION:
I
have a question concerning a dream I had when I was 12. Now I am 22 but
I just thought of it again. I'm not much for math, but this question has
more to do with physics and the rules of the universe. So, my dream was
about Jimminy Cricket of "Pinocchio" fame sitting on the Jolly Green
Giant's shoulder while floating in the middle of outer space. In the
dream the Green Giant was two light years tall while Jimminy was like an
inch or two high. The question I woke up with was how long did it take
each (Jimminy and the Giant)to see the Green Giants feet? Would it take
both the Giant and Jimminy two years to see the Giant's feet? Is mass in
anyway associated with the speed of time, with the greater the mass, the
faster the time? I think that the Giant would be able to see his feet
before Jimminy could. Sort of like how smaller moving objects, like
insects, blood and obviously atoms appear to be moving fast for someone
of human size, but does blood or an atom feel they are going
ridiculously fast? I know that this question must have been asked and
answered, but I don't know where to find the answer. And you guy's
appeared in a google seach titled 'ask a pysicist.'
ANSWER:
The
way you "see" something is to detect the light which came from it. Both
the giant and the cricket, at any given time, see light which left the
giant's feet 2 years ago. It makes no difference what the masses of the
detectors are.
QUESTION:
The question deals with the center of
gravity for a very specific object. Given a cylinder 12 inches in
diameter and 8 inches long which is made of a homogeneous mass
distribution; that has a 1.5 inch hole through it's center in the radial
plane and is subjected to a uniform field. Viewed from the radial plane
and aligned so as to see through the hole where would the center of
gravity be? Viewed from the radial plane but orthogonal to the through
hole where would the center of gravity be? I really don't need a
specific numerical value but only to know if the center of gravity moves
or does it stay located at the same place and is it the center of the
volume?
ANSWER:
The center of gravity is independent of any
external field and independent of how you view it. This object has the
center of gravity on the axis of the cylinder and 4 inches from one end.
QUESTION:
Could antimatter ever be a threat to space travellers
especially for space travelers within a solar system?
ANSWER:
Certainly not in the solar system since if there were any significant
amount of antimatter we would certainly have observed its effects. There
is also no evidence that there is a significant amount of antimatter
anywhere in the universe. So, I would say, the answer to your question
is no.
QUESTION:
I had a question about gravity. I have read that
Einstein said gravitation is caused by geodesics and the tendency of
mass to follow them. Is gravity a force?
ANSWER:
A force is
something which causes an object which feels it to accelerate; so
gravity is certainly a force in the classical sense. What is the origin
of this force? That is what general relativity answers by saying that
space is warped by mass, that is the gravitational force results from
the geometry being altered by the presence of mass.
QUESTION:
I
am a librarian assisting a library patron. The patron says at one time
he had a book that gave him a formula to compute the weight of an
object. If you put an object, such as a car, on a tire or ball or
something that is pressurized, and you know the PSI, you can measure the
size of the point of contact with the ground (the flat surface of the
tire on the ground) and calculate the weight of the object.
ANSWER:
Consider a piston of cross sectional area A, vertical, which has a
pressure P under it and a weight W sitting on it and everything is in
equilbrium; for simplicity, neglect the weight of the piston itself or
imagine it to have been absorbed into W. We must not forget that there
is an atmospheric pressure Pa pushing down on the cylinder. Then
Newton's first law specifies that the sum of all the forces must add to
zero, and so PA-W-PaA=0 (pressure time area equals force) so W=(P-Pa)A.
But (P-Pa) is what is called the guage pressure, it is the pressure
which most pressure guages read, the amount over (or under) atmospheric
pressure. So 30 psi means, usually, 30+14.7 psi since Pa=14.7 psi. This
seems to me to be equivalent to your question. Let's check it for
reasonableness: suppose a car has each of its four tires in contact with
the ground by an area of 6"x4" and the tire (guage) pressure is 30 psi.
Then the weight of that car would be 6x4x4x30=2880 lb which is about
what cars weigh.
QUESTION:
Is it possible to accurately measure
the speed of a moving vehicle by just watching it?
ANSWER:
Well,
I guess that depends on what you mean by "accurately" and what you mean
by "watching it". In order to make an accurate measurement of speed you
need to measure a time accurately and a distance accurately. Hence, if
you know the distance between two landmarks and time the car from one to
the other, its average speed is the ratio of distance/time. If you use
your experience to judge the speed, I would call that estimating the
speed not measuring it.
QUESTION:
If the moon were to leave earth
orbit into space, what would be the effect(s) on earth .
ANSWER:
The most noticeable would likely be that the tides would nearly stop.
Obviously, there would be no more solar (or lunar) eclipses. It is well
established that many biological systems depend on the timing of the
phases of the moon to time their functioning, but I am no expert on
that. The moon also affects the precession of the axis of the earth, but
this is a pretty small effect.
QUESTION:
what is the difference
in brightness of three lamps if they are connected in parallel/series
ANSWER:
I assume they are identical. I will also assume that
the light intensity is proportional to the power dissipated by the bulb;
this is not a very good approximation because the resistance of tungsten
wire is dependent on its temperature which is in turn dependent on the
current through it. Then brightness depends on power which is
proportional to V2 where V is the voltage across the bulb. The bulbs in
series will have only 1/3 the voltage across each as the bulbs in
parallel, so they will be only 1/9 as bright.
QUESTION:
;
Is there
a scientific proof that the atom is neutral?
ANSWER:
Basically
you are asking if the magnitudes of the proton and electron charges are
equal. Many very sophisiticated experiments have been done and the best
results to date indicate that the charges are equal to an order of about
10-21 where the magnitude of the electron charge is 1. In other words,
you would have to go to at least the 21st decimal place to see any
difference.
QUESTION:
What keeps the protons and electrons
together to form an atom?Gravity?Let`s speak on a simple atom of
hydrogen.How can the proton+ which is 1840 the mass of the electron- be
electrically balanced?
ANSWER:
The Coulomb force holds the atom
together; this force is due to the electrical charges on the p and the e
and those are equal but opposite in sign (there are two kinds of
charge). Gravity is totally negligible in atoms and the relative masses
of the two has nothing to do with the problem. Actually, that is not
quite true: if a proton and an electron had equal masses they would
orbit around a point halfway between them but this has nothing to do
with gravity.
QUESTION:
The medieval model of the solar system,
which places the earth at the center and the other planets (including
the sun and moon, per the medieval definition of "planet") in orbit
about it, is incorrect; however, if one makes a mathematical model of
the solar system by, e.g., assigning a position vector to each object,
and then subtracting earth's position from each object, one obtains what
seems to be a consistent, working geocentric model. In fact, it vaguely
resembles the less popular medieval model designed by Tycho Brahe.
Is there a reason that this model is inaccurate? It seems that the
heliocentric vs. geocentric argument is really just a question of which
reference frame should be preferred, when in fact there is no preferred
reference frame. Granted, the geocentric model I have suggested is
cumbersome and less useful for practical purposes, but it seems that it
is accurate. Most people believe that the sun is at the center of the
solar system and that ignorant persons of the past believed that the
earth was at the center. It seems more appropriate to say that one can
arbitrarily choose a center, and that ignorant people of the present
think that the choice of center is important.
Am I wrong? I have
been really curious to discover whether or not I'm just missing some
important point.
ANSWER:
Suppose that you are in a very large
rotating drum (they have rides like this at an amusement park
sometimes). You perceive yourself as being pushed into the wall and if
the drum spins fast enough you will be crushed by this "force". What is
actually happening is that, because you move in a circle, you are
accelerating even though your speed stays the same because the direction
of your velocity is constantly changing. Because of Newton's second law,
a force is required to keep you moving in this circle and the wall of
the drum exerts a force on you to achieve this acceleration. Now suppost
there is a man at rest standing in the center of the drum. He feels
nothing at all. Now, you want to say, "Let's choose me as being at rest
and the other guy going in a circle around me; that will be just as good
a description of the situation." But, alas, as you can see, there is a
world of difference. If two objects have constant velocity it makes no
difference which you consider at rest, but if one is accelerating and
the other is not, they are not equivalent. Finally, you know that the
earth moves the way it does because there is a force on it by the sun;
the sun feels the same force. But since the sun is so enormously more
massive than the earth, there is no way this force could cause the sun
to move in an orbit around the earth.
QUESTION:
Why gravitational
constant cannot be determined accurately just like c=299792458 m/s.As
far as possible this was the result-: G=6.6732 X 10^-11 in units -m^3
kg^-1 s^-2.
ANSWER:
There are several answers. First, since the
meter is defined in terms of the distance light travels in a given time
interval, the speed in m/s is, essentially, a definition and not a
measurement. Still, in order to make this definition, the speed of light
had to be measured very accurately in terms of the older definition of
the meter. The speed of light (or anything) is relatively easy to
measure accurately: if you have very accurate clocks and rulers you can
measure a speed very easily. The gravitational constant, on the other
hand, requires that you measure very accurately a mass (not too hard), a
length (not too hard), and a force. But the gravitational force between
two laboratory-sized masses, say a couple hundred kilograms, is very
difficult because gravity is nature's weakest force. A group at the
University of Washington has been performing innovative experiments for
many years trying to improve the accuracy of G.
QUESTION:
Has
any 2 (atleast) of the 4 fundamental forces been successfully unified
just like electricity was joined to magnetism earlier?
ANSWER:
The weak interaction has been unified with the electromagnetic
interaction; one refers to the electroweak force. The weak,
electromagnetic, and strong forces have been unified into what is
referred to as the standard model of particle physics. Gravity is the
odd guy out.
QUESTION:
The law of physics are the same on every
point of the surface of the planet Earth or not?
ANSWER:
If it
is truly a law of physics, it is true everywhere in the universe.
QUESTION:
Please can you explain what happens to the energy released
by the shattering of a glass on a hard surface? We are told that the
energy on Earth has remained constant since the formation of the planet
so what is the fate of the energy produced by this event?
ANSWER:
What makes you think energy is released? Why does a piece of glass not
just spontaneously break? The fact is, you must put energy into the
glass to make it break. If you drop it, it has kinetic energy when it
hits and then the surface does work on it by exerting forces on it. So
the question should be what happened to the energy which got put into
the glass to break it. It takes work (energy) to break molecular bonds
which were holding the glass together before it broke; there goes some
of the input energy. It makes a big crash; there goes some more of the
energy (sound). It will heat up a little bit; there goes some more of
the energy.
QUESTION:
What sort of interaction between the atoms
and photons makes them to be reflected (bouncing of the mirror) and/or
refracted (like through diamond) ?.If the answer involves quantum
mechanical implications does that pose any limitation to the possible
making of perfectly reflective mirrors?
ANSWER:
Photons interact
with electrons via the electromagnetic force. However, it is much more
fruitful to understand reflection and refraction by considering light as
waves. Then, whenever a wave encounters a medium of a different index of
refraction (that is the light travels at a different speed) it has the
possibilities of either reflecting or refracting. The amount of each
depends on numerous things, particularly angle of incidence, both
indiexes of refraction, and polarization. There already is a perfect
mirror which is total internal reflection which is used for fiber optics
for example. (Please note that I say "perfect" in a hypothetical way
since no surface is perfectly smooth and all media absorb light, so no
reflection is really 100%.
QUESTION:
Fusion of (ionized) hydrogen
molecules is done by increasing their temperature AND squeezing them
using powerful electromagnets.(right?). If so, is it possible to "FUSE"
them under normal room temperature just by indefinetly increasing the
electro-magnetic force?. If so possible, what about "FUSION" under
temperatures near 0 Kelvin ?
ANSWER:
The magnetic fields are not
to "squeeze" them but to confine them. The high temperatures are
required so that the positive ions have enough energy (that is enough
speed) to overcome the electric repulsion from other positive ions. They
need to get close enough to feel the nuclear force for fusion to occur
and slow ions cannot do this. Furthermore, magnetic forces are
perpendicular to the direction of motion so this force cannot squeeze;
also, the magnetic force is proportional to the speed of the particle,
so the slower the particle is moving (cold) the smaller any magnetic
force is.
QUESTION:
Are there any acceptable alternatives to the
current Big Bang model of the Universe? What are they? What is the best
evidence for the Big Bang model?
ANSWER:
I know of no reputable
astrophysicist who would not accept the big bang as the only viable
theory of the beginning of the universe. This is not to say that there
are not problems (like where did all the energy come from?). The best
evidence for the big bang are the microwave background and the fact that
the universe is observed to be expanding out from a single point. A more
interesting question to most astrophysicists than the birth is the
ultimate fate of the universe; answering this question involves the
currently fashionable topics of dark matter and dark energy.
QUESTION:
SIr why does gravity so different from other forces that
it doesn't depend on the mass of the object where the gravitational
force acts?
ANSWER:
I guess you are asking why all objects have
the same gravitational acceleration; the reason is, simply that the
acceleration is inversely proportional to the mass but the force is
proportional to the mass and so mass cancels out. See an earlier answer
for more details.
QUESTION:
am a member of a group of people with
an interest in space & the universe. We have been having a debate that
is no closer to being solved than when it first arose. This is topic
being debated: If an alien race were to live on a planet several light
years away from Earth, we know that Earth would look like a star in
their night sky. We also know that the light they saw would've left
Earth many many years ago; perhaps even when the dinosaurs lived. If
they were to have a telescope SO powerful that it could zoom in on the
living animals on the surface of Earth, would they be zooming in to see
the animals of present-day Earth? Or, would they be looking at the
dinosaurs? I would VERY much appreciate if you could help us in finally
putting this debate to rest.
ANSWER:
To see something, your eye
(or telescope) must detect light which was emitted from that object (or
reflected from it). So, when you look at a friend who is 100 m away, you
are not seeing him as he is right now but how he was 100/3 x 108=3.3 x
10-7s ago. 1/3 of a millisecond is a quite measurable time. Now suppose
you are on a planet which is 100 light years from earth. When you see
the earth you are seeing as it was 100 years ago because a light year is
the distance light travels in a year. The moon is 1.3 light seconds from
the earth and the sun is 8.3 light minutes from the earth. So, when you
see the moon you are seeing it as it was 1.3 seconds ago. If the sun
were to blow up right now, you would not know it for 8.3 minutes.
QUESTION:
Is there a thought experiment that shows (we can deduce
from it) how mass increases at relativistic speeds just as there's
plenty of such to show how coordinates transform?
ANSWER:
I am
not aware of a simple explanation such as those used for length
contraction and time dialation. In fact, there is no particular need to
even say that mass increases; what you must do is redefine momentum such
that momentum is conserved for an isolated system and one possible
interpretation of this redefinition is that mass increases. See my
earlier discussion of this topic.
QUESTION:
In the phenomenon
of polarisation, when a ray of light is passed through a crystal, the
ray splits into two, on the basis of the direction of vibration. How is
it possible when the light is a combination of electric and magnetic
vectors vibrating in mutually perpendicular direction?
ANSWER:
An unpolarized beam of light has electric fields pointing in random
directions; for each ray there is also a magnetic field normal to the
electric field. Light which is polarized has all electric fields
pointing in the same direction and all magnetic fields are perpendicular
to the electric fields. It is convention to choose the direction of the
electric field as the direction of polarization but the magnetic field
is still perpendicular to that direction. The phenomenon you cite is
called birefringence and the split beams have different polarizations.
QUESTION:
why do the astronomers say that viewing an event like a
supernova is like looking back in time?
ANSWER:
Because they are
far away and when we witness the event, the light has been traveling for
thousands or millions or billions of years to get to us.
QUESTION:
is the energy carried by an infrared photon greater or smaller than the
energy carried by a visible photon light?
ANSWER:
The energy is
proportional to the frequency. Infrared has a lower frequency than
visible light, so the infrared photon has a lower energy.
QUESTION:
why do bats and owls have good night vision compare to humans?
ANSWER:
You have probably heard the phrase "blind as a bat"; well,
bats are not really blind but their eyesight is not very good. The way
they "see" using sound waves like radar: they emit ultrasound which then
bounces off things in their environment and they are able to navigate by
hearing the echos. They might as well be blind. Owls, however, have very
good night eyesight. There are several things about their eyes which
give them good night vision:
Their eyes are quite large,the iris can
open very far to let in more light,the eye is cylincrical rather than
spherical which allows the retina to be larger,the retina is packed with
a great many "rods", cells most sensitive to low-level light (cones, the
other type of vision cell, allow color vision), andthe back of the
retina is reflective which means that light which does not interact with
the rods on its way in gets another chance.Most animals have better
night vision than we do because of the reflective layer called the
tapetum lucidum which we do not have. That is the reason that the eyes
of many animals at night tend to shine when light is shined at them--it
is reflected back.
QUESTION:
Why does the fundamental wavelength
of a string increase as the tension on the string increases?
ANSWER:
You are putting the question wrong since "fundamental
wavelength of a string" really has no meaning. The fundamental frequency
of vibration of a string clamped at both ends depends on the length of
the string and the speed of waves in the string. For the fundamental,
the wavelength on the string is 1/2 of a wave and the velocity is
proportional to the square root of the tension. The wavelength l on the
string stays the same as tension increases but velocity v increases. The
frequency with which the string vibrates is given by f=v/l, so the
frequency increases when the tension increases (which is, of course, the
way you tune a stringed instrument). If you are asking about the
wavelength of the resulting sound (which has frequency f) then it is
given by ls=vs/f where vs is the speed of sound in air and ls is the
wavelength of sound in air, so that wavelength is shorter when the
tension is increased because the frequency is larger.
QUESTION:
;
I understand the theory behind evaporation - some molecules have average
kinetic energy that is great enough to enable them to escape the
intermolecular forces that hold them together as a liquid. I'm given to
understand that the kinetic energy is a Maxwell distribution? A bell
curve? Also, when evaporation occurs, the liquid becomes cooler, because
it, as a whole, has less energy. If this is so, why does evaporation go
to completion? So the majority (or large portion of molecules) dont have
enough KE to escape, and when the ones that DO have enough KE to escape,
actually do so, the temperature (and hence average KE) decreases for the
liquid - shouldnt this mean that LESS molecules have enough energy to
escape, and then evaporation will eventually stop?
ANSWER:
The
Maxwell distribution is not a bell curve since it cannot exist below
zero. And, this distribution of kinetic energies is for ideal gases. But
neither of those points are really germaine in answering your question;
the important point is that the distribution is something which has one
maximum the position of which depends on the temperature, approaches
zero as kinetic energy approaches infinity, and is zero at kinetic
energy equals zero. So, as you state, a small but nonnegligible number
have kinetic energies large enough to escape; of course the direction of
the velocity matters too (velocities into the fluid will not come out
even with enough energy). Now, when the high-energy particles escape
they leave a gap in the distribution and so, in order to maintain the
same distribution of energies some lower-energy particles speed up but,
in order to conserve energy this means the whole distribution must shift
to a lower temperature (that is some other paricles slow down); that is
the cooling. Rate of evaporation does depend on the temperature, but
this is not a huge effect for modest temperature changes. In the real
world the fluid is usually in contact with its environment and tends to
come to thermal equilibrium with it; hence, when you set a glass of
water on the table in a room at a given temperature, water will
evaporate at a pretty constant rate as the room continually warms up the
water. The most important factor affecting evaporation rate is the
surface area and that does not change. Finally we get to the situation
where only the last single-molecule layer is left. Now the overriding
factor is how does it bond (or not) to the substrate. But even if this
last layer of water stayed there, you would likely judge the container
as bone dry because the number of molecules, while still very large,
would be tiny compared to a macroscopic amount of fluid (say a teaspoon
of water).
QUESTION:
When two objects "a" and "b" make an
elastic linear collision, the after ci=ollision velocity of object "b"
is given by Vb'=(2Ma/(Ma+Mb))Va+((Mb-Ma)/(Ma+Mb))Vb And a similar
equation holds for object "a". As I understand it, these equations are
derived algebraically from conservation of kinetic energy and
conservation of linear momentum. Suppose the objects are billiard balls
and each is rotating about its center of mass with constant angular
velocity. If I assume no energy is lost due to friction when the two
surfaces are in contact (ok, maybe not realistic, but it doesn’t seem
too unreasonable for an approximation ??), would analogous equations
hold for angular velocities? ie, can I replace mass by moment of inertia
and replace velocity by angular velocity in the above equation to get
after collision angular velocity? I can’t see why not, given that
angular momentum and rotational kinetic are conserved, but I have not
seen such formulae anywhere.
ANSWER:
The equations you quote
are true only for one dimensional collisions, collisions where all the
velocities before and after are directed along a line. There is a much
more general solution if the balls scatter to different directions. You
are right, angular momentum must also be conserved if the balls come in
with spins as long as the table is frictionless; otherwise the table
would exert an external torque. Also, the angular momentum due to the
velocity of the balls could not be ignored; they have no such angular
momentum in a head on collision, but that would probably not be the case
usually. In addition, the pertinent inertial parameters would be moment
of inertia, not mass. If there were friction when the balls were in
contact, angular momentum would still be conserved but energy would not,
further complicating the problem. So the answer to your question is a
resounding no: there is no such simple equation for the real world
situation. The problem is sufficiently complicated that numerical
methods on a computer would likely be required to make accurate
prediction.
QUESTION:
The compressions and rarefactions of sound
waves generate adiabatic temperature fluctuations in the medium (take
air). Is there any limit to the temperature fluctuation? or., is it
possible to create sound waves with such an intensity that TEMPERATURE
inside COMPRESSION reaches SEVERAL THOUSANDS (if not possibly millions)
of degrees (and temperature of rarefaction reaches NEAR ABSOLUTE ZERO)?
(it is useful to completely sterilise the air)..
ANSWER:
Let's
look at the pressure fluctuations in a sound wave. At the threshhold of
pain, the loudest sound you can hear without feeling pain, the pressure
variations amount to about 30 N/m2; compare this to the pressure of the
air, about 100,000 N/m2. I believe that the resulting local temperature
fluctuations would be negligible.
QUESTION:
How would I draw a
diagram that shows refraction of light that causes "water-like" mirages
on the pavement.
ANSWER:
I plagarized this from Tipler's
excellent book Physics For Scientists and Engineers, Freeman/Worth
Publishers.
QUESTION:
Why does a diamond glitter so much?
ANSWER:
In a nutshell, it is because diamond has a very high index
of refraction, 2.42. For reference, the indices of refraction of glass
and water are about 1.5 and 1.3 respectively. What this means is that
light travels much more slowly in diamond than in air and the result of
this is that it is very much bent when it goes from air to diamond or
vice versa. It also has the effect that much of the light which enters
the diamond does not go through but is reflected back (due to something
called total internal reflection, also the way that fiber optics works).
This effect can be accentuated by cutting the diamond cleverly and that
is the purpose of the facets. Therefore, the "glittering" is because
most of the light which strikes it bounces back toward you.
QUESTION:
I am learning about magnetos in school, and we were
taught that they have a tendancy to arc at high altitudes. Why is this?
Does the Permittivity of air change with temperature and pressure?
ANSWER:
The only thing I found about this topic is very
interesting. It says that the arcing is temperature dependent, not
altitude dependent. Thus, when a pilot takes off the temperature of the
coil is relatively low but, as time goes on, the temperature of the
magneto gets higher and, of course, this will be happening at higher
altitudes so the pilot reports that the magneto problems occur at higher
altitudes but the culprit is really temperature. You can read a more
complete explanation here.
QUESTION:
If the effects of general
relativity are taken into account then does mass of an object A near
another large massive object B depend on A's distance away from B?.
QUESTION:
Consider this situation where a heavy ball of'rest mass'
of value 'm0' be thrown upwards at velocity 'v' such that it reaches the
height 'h' before falling back; according to the law of conservation of
mass-energy, the sum of kinetic energy,potential energy and the energy
of 'rest mass' (m0c^2) are conserved at ground as well as at height h.
But the gamma factor isn't same. Let m1 be the relativistic mass due to
velocity at ground and m2 be the 'rest-mass' at height h. Apparently
m2=m1 since the mass-energy is conserved. but m1=m0*gamma(v) at
ground,hence m2 = m0*gamma(v) at 'h'. clearly the gravity was little
less at 'h' than it was at the ground. Does that mean that the
"rest-mass" will be more under less gravity?
ANSWER:
These two
questions both essentially ask the same thing--what is rest mass in
general relativity. Having done a little research, I find that this is
not an easy question to answer because several different definitions are
used. A discussion of this question would be too lengthy for this site,
but there is a good discussion at Answers.com.
QUESTION:
A
polythene rod can gain a negative charge when rubbed with a cloth. a)
Explain, with reference to electrons, what has happened? b) Why is
difficult to detect any charge on the cloth?
ANSWER:
This is
called the triboelectric effect. In fact, for charge to be transferred
from one to the other, only contact is required, not rubbing. Different
materials are placed in the "triboelectric series", those near the top
tend to give up electrons (become positively charged) and those near the
bottom tend to gain electrons (become negatively charged). Polyethylene
is near the bottom and wool or silk near the top, so the polyethylene
gains electrons on contact. The magnitude of the effect depends on many
different things and is generally not very predictable. You can read a
detailed explanation in Wikepedia. I am not certain why the charge on
the cloth is not so easy to detect, likely that it is easier for
something to gain electrons from the air (lose positive charge) than to
lose them (lose negative charge). Or maybe it is because the cloth has
so much more surface area over which to spread the charge. Or maybe the
sharp points (fibers, rough areas, etc.) in the fabric encourage corona
discharge.
QUESTION:
How can you tell if a point is 180 degrees
out of phase?
ANSWER:
I presume that you mean phase relative to
some other wave. First, define a periodic wave: it is one which, after
some elapsed time T (period) repeats exactly what the wave did since the
time t=0 until time t=2T, and so on. One could also define it in terms
of space: it is one which, at any particular time, repeats its shape
when you travel along a distance l (wavelength). Let us call the the
time of the beginning of the wave t=0 and the time of the end of that
one period t=T. Then 0 corresponds to 0 degrees and T corresponds to 360
degrees. Thus, the exact middle of the wave corresponds to 180 degrees.
Now, if another wave of the exact same shape is such that its beginning
is at t=T/2, it is said to be 180 degrees out of phase with the other
wave. An example of two waves 180 degrees out of phase (red and black)
is shown at the right. Notice that if you were to add these two waves up
you would get zero; that is another way you can tell if two waves are
180 degrees out of phase. You really should think of waves, not points,
as having relative phase.
QUESTION:
what would be the weight of
a astronaut standing on the moon whose earth weight is 180lb
ANSWER:
The acceleration due to gravity on the surface of the moon is about 1.6
m/s2 and on the earth it is about 9.8 m/s2, so the weight of something
on the moon is (1.6/9.8)We where We is the weight on the earth.
QUESTION:
When an airplane engine spins, it creates an image of the
propeller standing still or barely rotating. You can also see this with
car tires, fans, or any other spinning things. What causes it to look as
if the propeller is barely rotating when it is at high rpm's?? Also, why
does the image change directions???
ANSWER:
I do not believe that
you will see this effect in sunlight, just artificial light which has an
otherwise imperceptible flicker. Also, you often see this effect in
movies or on television (you know, the wagon wheels on a western which
look like they are going backwards). The explanation is in an earlier
question I answered.
QUESTION:
How can photons exert pressure
(Nichols Radiometer) if they have zero mass?
ANSWER:
In special
relativity we find that anything, like a photon, with zero mass travels
with the speed of light and that it posesses both kinetic energy and
linear momentum. Since a photon has momentum it can transfer momentum to
something and thereby exert a force.
QUESTION:
G is the
graviational constant, but I don't know what it's worth. I don't know
what the mass of an electron is either, or a proton for that matter. But
what, according to the best numbers we have, would be the strength of
the gravitational field of a electron, proton, or heck, even a neutrino
be?
ANSWER:
You can easily look these constants up. G=6.7 x 10-11
N m2/kg2, me=9.1 x 10-31 kg, mp=1.7 x 10-27 kg, Fg=Gmpme/r2 where r is
the distance between the two. I take r=0.5 x 10-10 m, approximately the
size of an atom. The force turns out to be about 4 x 10-47 N. To put
this in perspective, the electrical force between the two is about 9 x
10-8 N, so gravity is totally negligible on the atomic scale. The
neutrino mass is far less than that of an electron, so gravity plays
essentially no role in its interactions either.
QUESTION:
As I
was driving down the street looking at houses on my right, I noticed my
cars shadow on the houses (approching the streetlamp on my left). My
shadow caught up and passed me. Like a lever and I was the fulcrum.
Using this anology, if light approched an object closer that its shadow
was cast, wouldn't the shadow be moving faster?
ANSWER:
Yes.
FOLLOWUP
QUESTION:
You answered "yes" to my posted question about a
light approching an object that cast a shadow further than the distance
of the lights approach. Faster than light speed! I thought light was the
theoretical limit?
ANSWER:
I guess I don't understand your
question. There is no difference between your moving or the source of
light moving. For example, if you move at 50 mi/hr, the source is at
rest, and the shadow moves at 150 mi/hour then the shadow moves at a
speed of 100 mi/hr relative to you. If you are at rest and the source
moves with a speed 50 mi/hr then the shadow moves with a speed of 100
mi/hr relative to you. This assumes that the geometry has not changed
(distances between you and the source and the shadow. The "speed limit"
is that nothing can move faster than the speed of light, not, as you
seem to suggest, faster than the source of the light. However, it is
subtler than this. In fact, the shadow may move faster than the speed of
light because the shadow is not "something". You more often see the
example of taking, for example, a laser beam and shining it on the moon;
now rotate this laser very fast so that the spot on the moon moves
faster than the speed of light (which is pretty easy to do). But, that
spot, again, is not "something". The acid test is that if you imagine
the shadow moving (more quickly than the speed of light) from point A to
point B, you must not be able to use this moving shadow to transmit
information from A to B.
QUESTION:
This question deals with
free-float. An object is falling toward earth. A tunnel has been
previously excavated completely through the earth at exactly the
location of the object's landing, through the core and out to the other
side of the planet. The object continues its fall through the tunnel
without touching the sides of the tunnel. I know the earth's rotation is
an issue, but imagine that the object makes it through untouched. Where
would the object stop its fall? Newtonian gravity was described as an
attraction to the center of the planet. But that is no longer our
understanding of gravity. Would the object, travelling at its terminal
velocity exit the earth on the opposite side, travel up into the air,
then fall back to earth? Or would the object travel just to the surface
on the opposite side, then fall back into the hole, thus continually
boomeranging through the earth? Or maybe something else?
ANSWER:
I
recently answered this question.
QUESTION:
Have you seen '
YouTube - Walter Lewin Makes a Battery out of Cans and Water ' I have
never seen anything like it !! My friend asked me to give it my best
shot.. we are both in our 50's, and not students.. My response is below.
Do you know how this works?
ANSWER:
This is called Kelvin's
thunderstorm or Kelvin's waterdrop electrostatic generator. There is a
pretty good explanation here.
QUESTION:
Which is the difference
between matter and waves? Which is property that says that matter is
matter and waves are waves?
ANSWER:
Everything is both particle
and wave. If you look for a particle, you will find one. If you look for
a wave, you will find one. The classic example is light. If you take
light of a particular color (wavelength) and do an interference
experiment (for example the Young double slit experiment) you will only
be able to understand the experiment if you say "light is a wave". If
you take the very same light and shine it on a metal and measure the
properties of the ejected electrons (photoelectric effect) you will only
be able to understand the experiment if you say "light is particles".
QUESTION:
If Resistance of super conductors is ZERO then how would
we calculate amperes if a current is flowing through it formula:-
Amps=Volts / Resistance.?
ANSWER:
Ohm's law is not universal, it
only applies approximately to some materials under some conditions.
There is no reason to suppose a superconductor is ohmic (obeys Ohm's
law) but it does: V=IR, so if R=0, then V=0 no matter what I is. So a
current may flow with no potential difference. Another way to say it is
that a superconductor is everywhere at the same potential regardless of
any current flowing through it.
QUESTION:
If two hydrogen atoms
are sitting alone next to each other, and they then combine to form a
hydrogen molecule, what happens to the energy produced by this reaction?
What form is it in?
ANSWER:
This is just a chemical reaction, and,
as in most exothermic reactions, the energy appears as heat. On a more
microscopic scale, the energy is in the kinetic energy of the H2
molecules.
FOLLOWUP
QUESTION:
My question now is what kind of
motion does the hydrogen molecule acquire? When the (identical) hydrogen
atoms snap together to form the molecule they are moving straight at
each other; I can't picture in which direction the molecule would move
away, or is it the case perhaps that the molecule wouldn't actually move
away, rather the bond between the atoms would stretch and contract in an
endless oscillation (endless anyway until we introduce something else
into the system such as other molecules for this one to bump into)?
ANSWER:
If the two were moving in opposite directions with equal
speeds, then they would have to be at rest afterwards (that is their
center of mass must be at rest). So the energy would have to be in
internal energy of the molecule, either rotating or vibrating. In this
case, the excited molecule would either break back apart or would decay
to the ground state via radiation. These "inelastic" mechanisims for
conserving the total energy could happen also in cases where the two did
not happen to have zero linear momentum before the collision. So, if you
want to understand it completely, it is more complicated than just an
increase in temperature.
QUESTION:
In a nuclear reactor, a
neutron hits a uranium atom, causing an explosion, then a chain
reaction. Where does the first neutron come from?
ANSWER:
A
fissile material, like uranium or plutonium, will usually have a small
probability for spontaneous fission, that is fissions just happen
randomly in the material. Therefore you don't really need a source, your
fuel will provide needed neutrons to get the chain reaction started.
However, although I am not a nuclear engineer, I suspect most reactions
have a separate neutron source. The best known source historically is to
take an alpha particle emitter and coat it with a light nucleus like
berylium and there will be a reaction with neutrons as one of the
reaction products; one is the PuBe source, using plutonium and berylium.
you can learn form by looking for neutron source in Wikepedia.
QUESTION:
What are the properties of the cambdien rods that absorb
neutrons in a reacto to control the rate of reaction?
ANSWER:
I
believe you mean cadmium. There are hundreds of stable nuclei and you
can shoot a slow neutron at any nucleus and there will be a probability
that the neutron will be absorbed. This probability is quantified by a
quantity called the neutron absorption cross section s, the larger the
probability the larger the cross section. Some cadmium isotopes have
unusually large values of s.
QUESTION:
what happened after
Galilio threw the two balls?
ANSWER:
It is my understanding that
the experiment probably never took place, that is it is an apocryphal
story. See this link. If it did take place as legend has it, the two
balls of different weights would have hit the ground approximately
simultaneously.
QUESTION:
How was the speed of light calculated?
ANSWER:
I believe that the first part of an earlier answer will
answer your question. Essentially Maxwell's equations predict waves
which travel at the right speed.
QUESTION:
One thing that has
always been a
QUESTION:
When Rutherford fired "positive particles" at
gold foil, how was he able to separate atoms in order to "shoot" these
particles out? Similarly, when we talk about speeding protons around a
supercollider (like the Large Hadron Collider), again, how are these
protons isolated so they can be accelerated?
ANSWER:
Rutherford
used alpha particles which came from radioactive decay from heavy
nuclei, that is these positive particles exist charged in nature.
However, one can rather easily make alpha particles from helium gas by
simply removing the electrons from the nuclei. Similarly the protons for
a proton accelerator can be made by ionizing hydrogen. There are many
types of ion sources but the simplest to think about is simply a spark
which is nothing more than a plasma of electrons and positive ions in
the gas allowing current to flow (mainly the electrons) across a large
voltage difference.
QUESTION:
Hi, if you change the mass of a
ball rolling down an inclined plane and the angle of the slope is
constant the final velocity of the ball will always be the same no
matter what its mass is! I know this is because acceleration due to
gravity on earth is constant but is there a better explenation. Is it
because you break the weight of the ball into two vector components:
Force parallel which accelerates the ball down the slope and also Force
perpendicular which supplies the normal force to the ball. When the
weight of the ball increases the two vector components also increase and
Force parallel increases to a magnitude which accelerates the ball at
the same rate if its weight were less. F=MA then if M increases F
parallel will also increase and A remains constant?
ANSWER:
You
are making this harder than it need be. Essentially the reason that the
acceleration of gravity is constant is that weight is proportional to
mass and acceleration is proportional to mass and so acceleration is
independent of mass. See an earlier answer.
QUESTION:
When
sleeping on an air mattress does a person's body heat become lower than
if they were sleeping on a standard mattress? Is there any heat
transfer?
ANSWER:
I think your question is answered by an earlier
answer. If you sleep on the cold ground, for example, heat will be
transferred more quickly from you to the ground by convection if you are
on an air mattress than if you were on a mattress which is a poor
conductor and consists of many "tiny air mattresses" as explained in the
earlier answer.
QUESTION:
How is it that gravitational
compression can dominate electrostatic repulsion between protons in our
sun to result in temperatures sufficient to support fusion? I am
anticipating ionisation of hydrogen and separation of electrons and
protons - the former to outer regions and the latter to core.
ANSWER:
I do not see why you would assume that the electrons and protons would
rise and sink respectively. In fact, when the temperature becomes large
enough to ionize the hydrogen, you have a plasma; if this plasma did
separate into positive and negative parts, then you would run into
problems with the Coulomb repulsion. In the unseparated plasma, however,
electrons around protons shield protons electrostatically from other
protons (and vice versa).
FOLLOWUP
QUESTION:
Why is it not
reasonable to expect separation of electrons and protons under the
gravitational force within the sun given the vast difference in masses
of these two entities?
ANSWER:
The dynamic effects of gravity are
independent of mass; for example, drop a bowling ball (proton) and a
marble (electron) and both move exactly the same.
QUESTION:
A
50-kg box is pulled by a force at an angle of 30 to the horizontal. If
the box accelerates at a rate of 3 m/s2 , and coefficient of sliding
friction is 0.4, what is the magnitude of force pulling the box?
Problems I am having: Imagining the box where is the rope attached? At
the top right corner or the bottom right corner? I have not found a
simple way to figure out which is cos and which is sin. Please help! I
am studying for the MCAT.
ANSWER:
This is a problem where you are
supposed to view the box as a point mass, that is, you do not worry
about torques, etc; it is a simple Newton's second law, F=ma, problem.
It makes no difference where the rope is attached. The force has a
component horizontal which provides the acceleration, and a component
vertical which "helps the table hold up the box". So the equations to be
solved are: 50*3=-f+F*cos30 0=-50*9.8+N+F*sin30 where f is the
frictional force which is f=0.4*N and N is the normal force. So you have
three equations with three unknowns, F, N, and f.
QUESTION:
Aside from the big bang and black holes, are there other reasons to
consider the unification of gravity and the other forces (i.e. quantum
mechanics) a fundamental requisite for a complete theory of all that is?
ANSWER:
This is really a philosophy question rather than a physics
question. It is the philosophical bent of most scientists to seek to
understand nature using as few laws as possible. For example, if you
found the laws governing the flight of a baseball and the flight of a
basketball, you would be displeased to have separate laws for each; you
would seek an overriding law to describe the flight of anything.
QUESTION:
What is the medium through which electromagnetic waves
propagate? It's easy to see physical waves go through water. And I can
understand sound waves traveling through air. But what is the stuff that
carries electromagnetic waves?
ANSWER:
This is one of the classic
questions in the history of physics and its answer resulted in one of
the great revolutions in physics, the theory of special relativity. The
simple fact is that, since it is electric and magnetic fields which are
"waving" and these fields may exist in perfectly empty space, that
electromagnetic waves may propogate through perfectly empty space. They
are the one wave which requires no medium through which to travel.
QUESTION:
Is there a temperature at which fire will not burn? Lets
say that it is 10 degree F below 0. I think you can create a burning
fire at this temperature. But what if it is 200 or even 2000 degrees
below 0. Is fire still possible? Or is there a point at which humans
cannot create enough speed in the molecules to create flames? Just a
curious question. We were sitting around and couldn't come up with a
viable solution that we could all agree on nor could we discover the
answer online. We all agree that a human probably couldn't survive at
2000 below 0 but you know.... Thanks for any advice you might have..
ANSWER:
First of all, the lowest temperature is -459 F which is
absolute zero. It is tricky to just say the temperature at which you can
have something burn since it obviously depends on what you are burning.
For example, helium will not burn at any temperature and paper burns at
451 F (remember that book/movie Fahrenheit 451?). So a sheet of paper
below 451 F will not burn. But if you get it burning by elevating the
temperature at one corner, as it burns, since energy is being released,
the adjacent paper will heat up and burn until it is all burned out;
this is regardless of the temperature of the environment around it as
long as there is oxygen available to support the burning. Oxygen
liquifies at -130 F, so would not be available for burning unless the
paper were immersed in it.
QUESTION:
Chad Johnson,Wide receiver
of the Cincinnati Bengals football team recently raced a colt in a 100
meter race.Johnson covered the 100 meters in 11.720 seconds.How many
miles per hour was Johnson racing at?
ANSWER:
His average speed
was 100/11.72=8.53 m/s. This can easily be converted to mi/hr: 19.1
mi/hr. If you are interested in the details of the conversion, write
back.
QUESTION:
does light have weight?
ANSWER:
It
depends on what you mean by weight. If you mean the classical definition
of the force which the earth exerts on something by virtue of its mass,
then light does not have weight because it has no mass. However, if you
mean is light affected by a gravitational field, then you could say that
it has weight because it bends in a gravitational field as if it had
gravitational mass; this phenomenon is explained by the general theory
of relativity where a gravitational field is viewed as a warping of
spacetime in the vicinity of a mass. An earlier answer may be of
interest to you.
QUESTION:
What is the definition of dust and
what is it's constituents?
ANSWER:
According to Wikepedia, dust
is defined to be anything with a diameter less than 500 x 10-6 m. This
is half a millimeter, so it seems rather large to me. At any rate, dust
can be composed of anything which exists as a solid at the conditions of
the environment.
QUESTION:
Our sky appears blue because of the
sun's light is scattrated by air molecules, and our sun appears
yellow/red at sunset for the same reason. My question is will the sun
appear white if you were viewing it from the surface of the moon?
ANSWER:
On the moon the sky is black and the sun is white.
QUESTION:
I'd like to ask how can I convert Coulombs to Newtons,
Newton to Kilograms and kilograms to meters/second. For example how can
I find the acceleration that can be caused by the pressure of say, one
ton?
ANSWER:
You might as well ask me how to convert elephants to
tigers. All your requested conversions are impossible to do because the
units measure different quantities. A Coulomb is a measure of electric
charge, a Newton is a measure of force, a kilogram is a measure of mass,
and meters/second is a measure of speed (and a ton is a measure of a
force, not pressure, in English units). The only possible answer I can
give you is that in common (not scientific) parlance in countries using
the metric system of units a kilogram is often used as a measure of
weight; this is technically incorrect because weights should be
specified as Newtons but in this context 1 kilogram is the weight of an
object on the earth's surface which is actually 9.8 Newtons. Hence, one
could say that 1 kilogram equals 9.8 Newtons when referring to the
weight of an object.
FOLLOWUP
QUESTION:
Yes converting was the
wrong term. What about deriving these units? For instance, by the
coulombs law two positive point charges of 1 coulomb gives an in-between
repulsive force of 8.988×10^9 Newtons. How they got to that number?
ANSWER:
One additional thing: it is the force between the two charges
separated by 1 m. Many laws of physics cannot be derived, they must be
determined experimentally. Th way you come up with what that force is
(after having appropriate operational definitions of what a Coulomb and
a meter are) is to actually measure the force. Of course, you would not
use 1 C charges because that is a huge amount of charge (as is evident
from the huge force). Rather you would take, for example, two 1 mC
charges separated by 1 cm in which case the force would be 0.8988 N
because F=kq1q2/r2 where k is 8.988 x 109 N m2/C2.
QUESTION:
I
have what I think are two fairly simple and related questions about
transfer of heat when a person is sitting on cold metal bleachers.
First, do people lose heat faster through 1) the contact with the
bleachers, or 2) the exposure to the cold air (assuming no additional
layers on either their lower or upper half)? Second, when a person is in
contact with a cold surface, are pockets of air (like an air mattress) a
better insulator than a more solid insulation material (like a blanket
or dense foam cushion)? I am guessing that contact with cold metal draws
more heat than cold air, and that air is better than solid, but I don't
have the science to back it up.
ANSWER:
Heat is generally moved
faster by conduction than by convection, so your derrier will get cold
faster sitting on the bleachers than standing up; of course, since your
body is a source of heat, it is possible that you can actually warm the
seat up which then reduces the heat loss to the seat. The air is a
better insulator than something solid for the same reason. You are right
on both counts.
MORE:
One thing I should have added is that an
insulator made up of many little "bags" of air is better than an equal
volume of air (for example something like styrofoam). A convection
current in a big container of air can be set up such that air flows
quickly across the temperature gradient whereas that cannot happen in
the many little volumes. That is why, of course, it is better to fill
your walls with fiberglass insulation rather than just let it be filled
with air.
QUESTION:
I was thinking about hydrogen and the fact
that it is less dense than air, and water and the fact that it is denser
than air... Could the gpe gained by hydrogen, and the gpe converted into
kinetic energy by water be used? By that i mean, water is allowed to
fall, some sort of dynamo is turned by the falling water (as in power
stations) generating electricity. This electricity is used to
electrolyse water, producing hydrogen (and oxygen). Hydrogen is allowed
to rise, then when it reaches the top again, it is burnt, producing
water again. Surely there is an excess energy here or am i missing
something blindingly obvious? Surely the larger the distance travelled
down by the water and up by the hyrodgen, the greater the excess energy.
ANSWER:
Here is the problem with your plan: If you drop 1 kg of water
from a height of 100 m it acquires about 1000 J of kinetic energy. This
is the most energy you could get out of the turbine generating electric
power if it were perfectly efficient (which is of course impossible).
Now, the energy required to do electrolysis on that water is about 1.3 x
107 J. So you would have only enough energy available to do electrolysis
on about 1/10,000 of the water which fell.
QUESTION:
My
question is about the momentum light is know to carry . I was wondering
, if an object falls into the sun , won't it get slowed down by light
pressure so that it will posses less kinetic energy as it would without
light pressure. Doesn't that mean the sun-object system is losing energy
since the photons carry energy and that energy was used to slow down
(remove energy) from the object and as they slow the object down the
photon cease to exist (removing energy again).
ANSWER:
If the
photon transfers its momentum by being absorbed (perfectly inelastic
collision) then the photon disappears but its energy does not. The
object would get that energy in the form of heat or maybe atomic
excitations or ionizations. Energy of the system would not be lost when
the photon disappeared but just transformed to some other kine of
energy. You are right that the object will have a smaller acceleration
toward the sun than it would without light pressure, but I suspect the
difference would be trivial.
QUESTION:
Could you please answer
this question to me? it has had me wondering for about 3 months now:
What happens to energy carried by an electromagnetic wave when it
interferes with another? If energy carried by a EM wave is like E^2, (E
field intensity squared), and in phased interference of two waves, they
add linearly, energy would be 4 times greater instead of two! Another
way to pose the same problem, but with resulting energy null: Consider
that I send a wave from point A, and in its way it sums with another one
in point B, which travels in the same direction and way, so they share
their path from that point forwards. Imagine that they add with 180ş
phase difference: they will "destroy" (cancel) each other, so from B
onwards, there would be no EM field at all, right? then... where did the
energy of wave A, and the energy of B go?? Or maybe waves do not carry
energy at all? Energy conservation must hold.
ANSWER:
You should
not think of there being energy at a particular point in space due to
the presence of electromagnetic waves. Rather, there is a flow of energy
through each point in space. Although there is always zero energy at a
point of destructive interference, energy is flowing through that point.
I do not believe there is any to do your proposed experiment--they
simply cannot be aligned to share their paths exactly.
QUESTION:
I was told that with artificial gravity (based on rotating an object),
that you would have to have something very large in diameter in order to
provide the uniform gravity required by our bodies to avoid interfering
with blood flow. Is there a set number for this and how was it
determined?
ANSWER:
I am not aware of any rule. To set such a rule
would require knowing about physiology and how much of a variation we
could tolerate. You can make an estimate by making a reasonable guess.
Suppose that we can tolerate a 1% change over the height of a man, say 2
m. Then if R is the radius of the floor, then the radius at his head is
R-2 and so, v2/R=g and v2/(R-2)=1.01g. If you solve these two equations
you will find R=202 m, large as you say. If our bodies could stand a
larger variation, R could be smaller.
QUESTION:
Imagine two
billiard balls coming at each other in a direct head-on collision. The
billiard ball coming from the left is going 10 m/s, while the one from
the right is going 5 m/s. They have the same mass and little deformation
occurs in the collision. I say that the ball going 10 m/s stops dead
(for all practical purposes) and gives its momentum to the other ball,
causing it to reverse its direction of motion and move away at a speed
of 5 m/s. My friend says this is counterintuitive - that the ball with
the greater momentum should "win" (in his words). What's the correct
answer?
ANSWER:
Usually a billiard ball problem assumes a
perfectly elastic collision, so that is what I will do. The problem
cannot be solved without specifying energy loss in the collision, and
elastic means no loss. So, conserving both energy and momentum it is an
easy problem. I find that after the collision both balls have reversed
their directions; the one which came in with speed 10 m/s exits with
speed 5 m/s and the one which came in with speed 5 m/s exits with speed
10 m/s. A quick outline of the solution:
the mass does not matter,
so take it as 2 kg. The momentum before the collision is pb=2x10 +
2x(-5)=10 kg m/sThe energy before is Eb=˝x2x(10)2+˝x2x(-5)2=125 JThe
energy after is the same as the energy before,
Ea=˝x2x(v10)2+˝x2x(v5)2=(v10)2+(v5)2=125The momentum after is the same
as the momentum before, pa=2v10+2v5=10Here v10 and v5 are the velocities
after the collision of the balls with initial speeds of 10 and 5 m/s
respectively. Now solve these two equations for the two unknown
velocities and you will get -5 and 10 m/s respectively. (You will also
find a second solution, because the energy equation is quadratic, of 10
and -5 m/s which corresponds physically to a "miss".)
QUESTION:
Why
does not the lightening go in a straight line?
ANSWER:
Lightning
propagates by a series of small steps called leaders. Each leader shoots
forward about 150 feet, then a new leader, often in a different
direction, is formed carrying the electric current, etc. For the leader
to be able to carry the current, the air must be ionized and the field
relatively far from the cloud does not have an intense enough field to
do this. However, the field at the tip of a leader is strong enough to
do this. There is a pretty good discussion of the mechanisms of
lightning at this link.
QUESTION:
I know that Einstein's account
of gravitation involves the LOCAL interaction of masses. But Newton's
universal constant of gravitation, G, is global. Do we throw out G as a
consequence of the general theory of relativity?
ANSWER:
I am not
sure I understand your question. Newton's universal law of gravitation
is an empirical law, simply a mathematical description of experimental
data. On the other hand, general relativity is a theory which explains
why Newton's law is correct, because of the warping of spacetime in the
vicinity of gravitational mass. Hence, you do not have to throw anything
out.
QUESTION:
Is CONDUCTION of temperature --- none other than
inter-molecular (or inter-atomic) transfer of heat energy through
RADIATION? Or is there any other factor involved which makes CONDUCTION
different from such radiation transfer.
ANSWER:
No, conduction is
something different from radiation. If you heat up one end of an object,
the molecules will contain a higher vibrational energy than their lower
temperature neighbors and will transfer, via the forces between
molecules, energy to them. Think of two masses connected by a spring and
one of them is set vibrating; before long, the other will be vibrating
too. A simpler way to say the same thing is that the energy is
transferred by collisions.
QUESTION:
Would you answer a question
for me? Since a quark of a given flavor and its antiquark tend to
annihilate each other when they come together, how is it that a phi
meson (made up of a strange quark and its antiquark), a psi meson (made
up of a charm quark and its antiquark), and a upsilon meson (made up of
a bottom quark and its antiquark) can exist in a metastable state and
not immediately annihilate each other?
ANSWER:
There is no reason
why a particle and its antiparticle cannot exist in a bound state. The
best known example, perhaps, is positronium where an electron and a
positron appear in a ground state.
QUESTION:
Do gravitational
waves really take away the energy from system of rotating bodies? how
long will it take for earth to crash into the sun then?
ANSWER:
First let us establish that gravitational waves have never been directly
observed. However, there is indirect evidence where the energy of a
particular binary star system is decreasing at the rate which would be
expected if gravitational waves were being generated as predicted by
general relativity. The rate of energy loss depends on the masses of the
objects and, I am quite sure, the sun will run out of fuel and die long
before there is any noticable change in our orbit due to gravitational
radiation.
QUESTION:
I have a question about the twins paradox
that's been bugging me for a while. In it, the twin in the spaceship is
said to be under acceleration and therefore he ages more slowly than his
twin on Earth. But if no frame of reference is privileged, couldn't one
just as reasonably say that the spaceship remains motionless while the
Earth undergoes acceleration away from and then back towards it? In that
case, shouldn't the earthbound twin be younger when they reunite? The
same question would also apply to mass change due to acceleration: why
isn't it just as reasonable that the Earth (and every other object in
the universe) should gain in mass instead of the spaceship?
ANSWER:
There is never any question as to who is actually doing the
acceleration. When the traveling twin slows down he feels being smashed
against the front of his ship. The earth-bound twin feels no such force.
Also, the ship needs to burn its engines to accelerate, the earth does
no such thing. However, I very much dislike the explanation that all the
aging takes place during acceleration periods. See an earlier discussion
of this. Regarding mass, there is no mass change associated with
acceleration. However, a moving particle has increased mass and both
twins would agree, as long as they are moving, that the other has larger
mass.
QUESTION:
If gravity is understood in Relativity Theory as
a distortions of spacetime, how is the use of gravitons as the particle
of gravitational exchange reconciled with the relativistic model? Also,
can we profitably model the electroweak and strong forces as distortions
of spacetime?
ANSWER:
For your second question see the following
question. For your first question, see my earlier answer.
QUESTION:
I'm a senior in high school. Over the past few years I have obtained a
growing interest in theoretical physics. Anyway, recently I have been
thinking over general relativity, Einstein's law of gravitation, and the
Grand Unified Theory. One question has been bothering me. If the force
of gravity can be defined as the curvature of spacetime, why can't
electricity and magnetism, or any other force for that matter be
considered a curvature in spacetime. I'm sure the answer is alot to
explain in an email, so if you would rather direct me to paper's or
books, or simply telling me that this approach has been tried before, I
would be grateful.
ANSWER:
The answer is fairly simple, I
believe. In the theory of general relativity, mass "warps" the spacetime
around it so that it is curved. However, electric charge does not warp
spacetime. Electric charge is the source of electromagnetic fields and
mass is the source of gravitational fields. Also perhaps of interest to
you is that there is a good quantum theory of electromagnetism but there
is no satisfactory theory of quantum gravity.
QUESTION:
I have a
question about supercooling. Last year, a fisherman I know was changing
his lobster traps, and he checked the sandbags used to weigh down the
traps. When he took it out, the bag was well below freezing, and
immediatly began crystallizing the water in the air. I wonder if salt
water can be supercooled, and would the ocean floor be candidate for the
supercooling phenomenon?
ANSWER:
Two sequential questions, one
about supercooling and one about superheating; that's supercool! When
the water is very deep, the pressure is very high. If the pressure is
high, that will keep the water from becoming ice because it is necessary
that ice have a lower density than water, that is it must expand. So, if
the pressure is high enough, water will be below the freezing point but
not freeze. Now, bringing this water up to the surface where the
pressure is lower will allow it to solidify.
QUESTION:
I have
been researching zero kinetic energy and microwave fields so that I may
find the answer to a question between my brother and I. From all the
research I have gathered, I have not come up with proof that microwaves
(from an actual microwave oven, of any variety) can cause energy pulses
to increase and heat liquid well after the microwaves have ceased. Case
in point - If liquid is heated for a specified amount of time using
microwaves, and is then removed from the microwaves, can the kinetic
energy cause the liquid to continue to rise in temp for any duration of
time? Even after the microwaves are no longer affecting the liquid?
ANSWER:
Gee, I have no idea what you are talking about! I do not
know what you mean by zero kinetic energy. However, what you may be
asking about is a fairly well known phenomenon where a liquid will
become superheated in a microwave oven. Superheated is when a liquid has
a temperature above the boiling point but does not boil. This can be
dangerous since it is easy to cause the superheated liquid to boil
violently (just disturb it mechanically by putting a spoon in it, for
example). Maybe this is what you are referring to when you refer to a
continued rise in temperature; the temperature does not go up, it is
just that the liquid boils. I suspect the temperature would actually go
down to the boiling point when the boiling begins. For more information,
go here.
QUESTION:
There are two observers standing on a
stationary platform. A spark of light is emitted from a light source
that is equal distance between them. From the frame of reference of the
two observers, they will see the spark at the same time. If the platform
on which the two observers is moving and the light source remains in the
same spot as it was before. From the frame of reference of the two
observers, which would receive the light first? Why is this the
same/different from the first scenario?
ANSWER:
If there are two
observers at rest with respect to each other and their is a flash of
light halfway between them, they see it at the same time (regardless of
how the source itself is moving, as long as it is halfway between when
it flashes). So the answer to your question is that they will see the
light simultaneously. However, and here is the catch, if you are
standing on the ground and they are moving by you will not see them
observe the light simultaneously but the guy at the back will see the
flash first and then the second. Hence, you and the guys moving by do
not agree on whether or not these events are simultaneous. This kind of
thought experiment is one of the first hints leading to the theory of
special relativity which finds that time is not a universal thing but
depends on the motion of the frame you are in.
QUESTION:
Say
there was a 1.0g bee and it started out traveling north at 5.0m/s ( with
respect to the ground) and then as it was going along it collided head
on with the windscreen of a 10000kg truck that was traveling south at
20m/s ( with respect to the ground) . The bee bounces off the window at
40.0m/s - north (with respect to the ground) after an imapact lasting
0.08s. Obviously the bee started out moving north and ended up moving
south. this means it must have come to rest with respect to the ground,
during the collision. Doesn't that mean the truck which it came into
contact also stopped for an instant? Is that possible, a bee stopping a
truck?
ANSWER:
Let us calculate the average force which the
truck exerted on the bee during the collision time: F==ma=mDv/Dt where v
is the velocity; this is just Newton's second law. So, F=(10-3 kg)(40
m/s-(-5 m/s))/(0.08 s)=0.56 N north. Therefore the truck experiences (by
Newton's third law) the same force south. So the average acceleration
the truck experiences during the collision is a=F/M=(0.56 N)/(105
kg)=5.6 x 10-4 m/s2; that means that after 0.08 s the truck's speed will
be decreased by 4.5 x 10-5 m/s. So, I think we would agree that the
truck's speed will never be zero. I think your confusion comes from the
reasonable but untrue assumption that the bee and truck are at rest with
respect to each other during the whole time the collision is happening;
they will only be at rest relative to each other at one instant and that
will not be the instant when the bee is at rest but rather when the bee
is moving with the same (northward) velocity as the truck has.
QUESTION:
If I were to take an extended trip at close to the speed
of light, and my friend were watching me, he'd observe me staying young
as he grew old, due to time dilation. I would see him staying young as I
grew old. So here we have two conflicting realities. How can both of
these things be true?
ANSWER:
This is the well-lnown twin paradox
although it is not a paradox at all since it is fairly easy to show that
the earth-bound twin grows older. I have answered this question before;
click here.
QUESTION:
Fill a large pot with water. Mark the
water level. Remove a fourth of the water and freeze it. Place the ice
chunk back into the pot. Because of the lower density of ice, a portion
of the ice chunk is above the water level. Even so, is not the water
level back to the original marked water level? In addition, does not the
water level remain the same as the ice melts? The Arctic is a floating
iceberg, while Antarctica is a landmass. Presently, areas of the Arctic
are losing mass, while Antactica is gaining. Global warming enthusiasts
warn that the melting of ice in the Arctic will cause the oceans to rise
by various amounts. If the above is true, the cubic miles of ice at the
Arctic are already reflected in present ocean levels.
ANSWER:
You
are correct that if all floating ice melts it will have no effect on the
ocean level. However, it is my understanding that there is plenty of ice
on land to cause a problem should it melt (glaciers in Greenland,
Canada, Antarctica, Siberia, etc.). I was unaware that mass of
Antarctica was increasing; what is your source for this?
QUESTION:
Suppose a beam of light is travelign perfectly back and forth between
two mirrors, hitting the same point on each mirror each time. Suppose
these mirrors were to come closer to each still maintaining the perfect
back and forth beam. Finally suppose these mirrors were to phase
together. What would happen tot he beam of light? during thsi process
and after the process?
ANSWER:
There are real world problems with
your question. First, there is no mirror sufficiently reflective so that
your experiment can be done (see an earlier answer). If there was a
photon between two idealized mirrors, bouncing back and forth, when the
spacing started being comparable to the wavelength of the light you
would find that only at some spacings could you put in a photon at all.
These are integral multiples of half the wavelength of the light.
QUESTION:
Two protons are moving side by side (parallel). Is there
a magnetic interaction or just an electrical interaction?
ANSWER:
Sorry to be so long getting back to you, but I had to go back and review
some relativity. There is a magnetic interaction. Imagine you are in the
rest frame of one of the protons. Then it sees only an electric field
from the other (which is also at rest); choose a coordinate system such
that the field it sees is E=zE where z is the unit vector in the z
direction. So the force it feels is in the +z direction and of magnitude
eE. Now, view this from a frame moving with speed v in the +x direction.
Because of the way that the electric and magnetic fields transform (I
don't think you want me to go into details) there is now both an
electric and magnetic field at the proton we are watching: E'=gEz and
B'=(gv/c2)Ey where g=(1-v2/c2)-1/2, c is the speed of light, and y is
the unit vector in the y direction. Now, in this frame the proton we are
watching has a velocity v=-xv where x is the unit vector in the x
direction. The force now is F'=eE'+e(v x B')=eE. (I will leave it to you
to verify that last step!) So, the force is exactly the same, but it is
composed of both magnetic and electric parts if the protons are moving
in our frame.
QUESTION:
When light is "slowed down" because it
enters a different medium what exactly is happening? How is lights
velocity rduced throught water or glass? Why does this refraction
happen?
ANSWER:
The answer is a little lengthy, so bear with me.
There are two important constants in electromagnetism (EM) which
essentially specify how strong the electric and magnetic forces are in a
vacuum; these are e0 (electric constant, called the permitivity of free
space) and m0 (magnetic constant, called the permeability of free
space). It turns out that when you do the mathematics you find that the
EM equations (called Maxwell's equations) predict waves which have a
speed of [e0m0]-1/2 and this speed just happens to be the speed of light
in a vacuum. However, things are different in a material: because the
material is composed of many charges and the charges are moving, the
whole medium is affected if exposed to electric or magnetic fields. For
example, an electric field will polarize the molecules and this
polarization will result in a weaker electric field than if the material
were not there. Hence the strength of the forces are different so we
need to measure new values of permitivity (e) and permeability (m) both
of which are larger than the free space values. So now Maxwell's
equations predict a new (smaller) velocity [em]-1/2. In a nutshell, the
speed changes because of the interactions of the electric and magnetic
fields of the light with the electric charges and currents inside the
material.
QUESTION:
I am revising some poorly-written curriculum
materials for my Integrated Technology class, and have stumbled upon
this paragraph: "Energy can not be seen since, unlike matter, it has no
mass. However, it can be measured, sensed, or otherwise detected. For
example, we cannot actually see the energy of a light bulb traveling
through air, but we can see its illumination reflected from this
laboratory manual or the walls of this room." While there is some
correct information here, the statement that energy can't be seen
strikes me as wrong. It seems to me the issues are: 1) We can only see
energy in the visible portion of the spectrum and 2) it must be directed
toward our eye for us to see it. The fact that light is not matter
doesn't, in fact, matter. In fact, I would say that we can't see matter
without (visible light) energy. Is my assessment correct (the
explanation, as written, is wrong or at least misleading), or can you
illuminate me on this subject?
ANSWER:
It is most unsettling to a
physicist to read garbage like this! Energy is, simply stated, the
ability to do work. It comes in all forms, not just electromagnetic
(light). A moving car has energy due to its motion (kinetic). A falling
skydiver has energy by virtue of his altitude (potential). A cup of hot
soup has energy by virtue of its temperature (heat). A bottle of
gasoline has chemical energy stored which can, as you know, be
exploited. To speak about "seeing" energy is ludicrous; can you see a
moving car, a falling skydiver, a cup of soup, a beam of light? It is
also inaccurate to say that energy does not have mass; as we know from
the theory of relativity, mass is energy--you know, E=mc2!
QUESTION:
Is quantum physics and quantum mechanics the same? If so,
what is their similarities? If not, what's the difference? What are they
classified under?
ANSWER:
Quantum physics usually means the
early insights and advances in the study of the quantum theory. It would
include Planck's explanation of black body radiation, Einstein's
explanation of the photoelectric effect, the Bohr model of the atom,
Rutherford scattering, DeBroglie's hypothesis, etc. Quantum mechanics is
much more complete and less phenomenological and involves considerably
more mathematics. There is, however, no formal definition of what each
term covers and they may be interchanged more or less as you like.
QUESTION:
A sky-diver is falling toward earth. A tunnel has been
previously excavated completly through the earth at exactly the location
of the skydiver's landing. He continues his dive through the tunnel
without touching the sides of the tunnel. I believe that Newton would
have had him stop at the earth's core. Where would Einstein have him
stop?
ANSWER:
First, since this is clearly an idealized problem,
let us neglect air friction (which is, of course, not negligible because
the skydiver has a terminal speed before he hits the ground). Until he
enters the tunnel he is accelerating with a constant acceleration down.
When he enters the tunnel, he experiences less and less force as he goes
deeper because there is less and less of the earth pulling on him (all
of the earth outside him exerts no force) until finally at the center he
has zero force on him but he has his highest velocity of the whole trip
since he has been speeding up the whole time. Now as he moves away from
the center he slows down. When he reemerges at the other end of the
tunnel he has exactly the same speed as he had when he entered it. He
continues until he reaches the altitude from which he originally jumped
at which point he turns around and begins the process all over again.
Newton an Einstein would both agree on this. If air friction were
included, he would not go as far and if he happened to stop at the
center of the earth, he would stay there forever. If the air friction
were included the general solution to the problem would be that he would
oscillate back and forth going less far each time until he finally
stopped in the center. There is an interesting aspect of this problem:
when the skydiver is inside the tunnel, he moves exactly like he were a
mass on an ideal spring.
QUESTION:
I was driving in my car
today and thought of my physics class I took a few years ago, and tried
to test my mental capability of remembering some simple concepts. I was
wondering if the acceleration of my car is constant relative to a second
car, is the acceleration also constant when comparing to a third car ?
Then I was wondering if the velocity of my car can reverse direction
when its acceleration is constant. And finally, is it true that my car
with a constant speed can not accelerate?
ANSWER:
If you mean
that the second and third cars are moving with constant velocities,
then, yes your acceleration as measured by any other car is the same.
This is the keystone of Galilean relativity and Newtonian physics since
it means that Newton's second law, F=ma, is "invariant", that is all
observers will agree on what the force is on an object. Yes, velocity
can reverse when acceleration is constant. The classic example, of
course is a projectile; if you throw a ball straight up its
acceleration, when it leaves your hand, is a constant 9.8 m/s2 down at
all times and it clearly reverses its direction at the top of the
trajectory. Acceleration is defined at the rate of change of velocity.
Velocity is a vector whereas speed is a scalar, the magnitude of the
velocity. Hence it is quite possible for you to accelerate if you move
with constant speed; for example, if you are moving on a circular
racetrack with a speed of 60 mi/hr you are constantly accelerating
because the direction of your velocity is changing.
QUESTION:
Is
it possible to use hollowed out asteroid, and spin it to produce
artificial gravity? While I read from one of the answers that a
spacecraft can only be a certain size/mass, now I am wondering whether
the same size, mass limit also has effects for hollowed out asteroid, or
since it has an extremely thick shell, the size/mass limit is a lot
greater?
ANSWER:
Anything which has the right angular velocity
can simulate gravity if you are inside it. For it to be a good
approximation, the size must be large compared to you so that your head
does not have a significantly different acceleration from your feet.
QUESTION:
How fast would somthing have to travel to creat a sonic
boom, so strong it could break glass? ( I seen it in a movie and it
seems like it should have been moving alot faster)
ANSWER:
For
there to be a sonic boom the source must move faster than the speed of
sound. Once there, a further increase in speed has little effect on the
strength of the boom. This is more determined by the size and geometry
of the source (a bigger airplane has a stronger boom than a smaller one)
and by its distance from the observer.
QUESTION:
I have a
calculator that converts "lb to kg" and vice-versa. If F=ma and in the
SI system my force in newtons would be my mass in kilograms times my
accleration (m/s/s). In english units my force would in lbs would be my
mass in slugs??? times my accleration in ft/s/s. How can the calcualtor
use kg (a mass) to convert it to a (force) lbs? I also use a scale that
has a button that that allows you to switch between kg and lbs when
"weighing or massing" things. I "weigh" about 220 lbs therefore should
my mass be (220/32) 6.9 slugs which would be the same as (in SI units)
99.7 kg's-but my weight in SI units is 2156 newtons. How is they are
using force and mass interchangeably? (I have been out of school a while
and used slugs but was also taught there are lbs-mass and lbs-force.)
ANSWER:
Pounds and kilograms are conventionally used both as a
force or a mass which is really too bad. Physicists do not do that.
However, one often talks about 5 kg of onions, for example and converts
that to pounds. To be really precise, some people refer to the
pound-mass and pound-force; a pound mass is the mass of an object which
weighs one pound-force. When a kilogram is converted into pounds it
means pound-mass. It is all very confusing and should not be worried
about too much. The problem arises mostly because the SI system has
mass, length, and time as the fundamental quantities and the English
system has force, length, and time. A slug is that mass which
experiences an acceleration of 1 ft/s2 if a force of 1 pound-force is
applied; almost nobody uses the slug except maybe some engineers.
QUESTION:
What is it about the oblong holes in a wiffle ball that
makes it curve so easily? There's a lot of information about curveballs
in baseball but not so much about the physics of a wiffleball. I was
just wondering if wiffeballs, which are hollow and have holes, curve for
a different reason than baseballs, which are solid and have seams.
ANSWER:
Anything which moves through the air has its path determined
by two things, gravity and air friction. To make an airplane lift off,
you must have a higher pressure under the wing than you do on top of the
wing. An airplane does this by the shape of the wing. A curveball
operates by the same principle except its asymetry of pressure is the
result of spin which causes the pressure on one side to be different
from the other. With a whiffle ball the holes cause the effects of spin
to be much larger (both because the holes disturb the air more than the
seams do and because the weight is smaller so gravity has a smaller
influence on the motion). I suspect the reasons for oblong holes is that
you can get different effects by spinning it about different axes.
QUESTION:
Assume a batter who is 5'8" tall and weighs 120 pounds is
coming up to the plate with a wooden bat, 26-28 ounces. Against an 80mph
fastball thrown from the major league distance of 60'6", and assuming
the ball makes contact with an acceptable point of the bat (somewhere
near the sweet spot), how fast does the batter have to swing the bat in
order to hit the ball: 100 feet, 200 feet, 300 feet, and 400 feet.
ANSWER:
This is a typical example of expecting elementary physics to
be able to give a simple formula for everything. The fact is that
elementary physics gives us the tools to start attacking real-world
problems like this, but we cannot simply apply simple physics to real
world situations like this. The batter does far more than just give the
bat speed and these details count. The distance is also determined by
the direction with which the ball leaves. The important thing you want
to focus on is the speed with which the ball leaves the bat and that is
greatly influenced by how elastic the collision is (wooden vs. aluminum
bats, for example). If you had some measure of elasticity, you could
easily calculate the speed of the ball after the collision using the
masses of the ball and bat before the collision by simply applying
momentum conservation. However, this is a very poor model for what
actually happens because the bat is not simply flying along by itself.
This whole question would be better addressed experimentally than
mathematically.
QUESTION:
how much energy is needed to enter the
earths atmosphere rather than being caught in an orbit? for example if a
person with a hyperthetical suit that could withstand entry through the
atmosphere jumped towards earth off a space station would they ever
return to earth or forever be in orbit around the earth?
ANSWER:
Your question is not correctly framed. It is not energy to enter the
orbit (whatever that means) which you should think of. Rather, it is
just a matter of knowing how the person "jumped toward the earth". What
determines what the orbit of anything will be is simply its velocity
(magnitude and direction) at some particular point. So, if you just
edged off the space station you would orbit along with it since both
satellites (you and the space station) had identical velocities. If you
push off really hard straight toward the earth, however, you would exit
with a different orbit and if this orbit at some point intersects
appreciable atmosphere, you would reenter. What determines whether or
not this happens is basically how hard you push off.
QUESTION:
If you have a light source going from piont A to piont B, and the
didtance is 50 million light years, (or whatever) and the source
completely die's, you now have a light beam traveling to point B,
(earth) and at the same time an asteroid breaks the beam by traveling by
it, you now have a light beam that has been broken, does the beam still
go, but now in two parts? Once the beam leaves point A, do you now have
a light beam all on its own?
ANSWER:
Let us suppose that the
source has been on for 1000 years when it goes out. You now have a beam
of light 1000 light years traveling through space with the speed of
light. If something crosses exactly in the center of the beam and
absorbs the light from the beam for one year, then you have first a beam
500 light years long, then a gap of one light year, then a beam 499
light years long.
QUESTION:
Hi, i recently thought of an
invention regarding the producition of electricity. I know that
electricity is produced by various methods but ultimately all it takes
to produce electricity is to spin a turbine. I was wondering if a
turbine had north magnets on it and another turbine was facing the first
and it south magnets wouldnt the magents attract and if one turbine was
spinning wouldn't the other? This would yield twice the electricity even
though it only requires on of the turbines to be powered. Would this
work or is it unfeasible?
ANSWER:
Ah, the never ending quest for
something for nothing! Why not just weld the two turbines together and
attach each to a generator? It would be the same thing as your using
magnets to "attach them together". The fact is that you cannot get more
energy (electrical) than you put in (from hydro, or burning coal,
nuclear fission, or whatever). And imperfect efficiency dictates that
you get far less out than you put in. Now, suppose that you get one
megawatt from the generator attached to one turbine; if you attach a
second generator and demand one magawatt from that also you will have to
put in twice as much energy.
QUESTION:
If a black hole is a
singularity, how can black holes be different sizes?
ANSWER:
They
cannot be of different geometrical sizes (because a singularity is a
point), but black holes have mass and they can have different masses.
QUESTION:
You build a long train on a very big circular track and
set it running at 100mph. On the roof of that train you build another
track, and set a second train running at 100mph, so the second train is
doing 200mph relative to the ground. Assuming infinitely strong building
material, and no atmospheric drag, infinite friction between wheels and
track, and that centripetal force doesn't throw the trains of the track
etc etc. Keep on building up and up infinitely. What happens to the
speed of trains at the very top of the infinite stack when they are all
doing 100mph faster than the train underneath them? and how many trains
in the stack to get to the maximum possible speed?
ANSWER:
Let's
not think about this circular train since accelerations cause problems
in special relativity and I think we can answer what your question is
without circular tracks and, in fact, without having them on top of each
other. Imagine trains on parallel trecks: train A is at rest, train B
moves with speed 100 mi/hr relative to A, C moves with speed 100 mi/hr
relative to B and so forth. There is no limit how many trains you can
add in this way but no train may move with a speed greater (or equal to)
the speed of light relative to any other. Thus, if you had 1050 trains,
the last train would not have a speed of 100x1050 mi/hr relative to the
first but would have a speed of just under the speed of light.
QUESTION:
ok this may be the holy grail of science and is mostly
unkown but.. The Large Hadron Collider in CERN is as u probably know due
to be turned on in november. Now i just have 2 questions one being a
concern of mine. Firstly if they do find the higgs mechanism to be true
or if they do find an equation for everything then what will its uses be
other than tick a box of accomplishments. Like could this mean we could
potentialy build new life, exploit matter and time...? and secondly I
assume that wen they turn this on they will gradually add energy rather
than full blast and potentially rip apart the universe? because I would
hope if they see its too much energy as they turn it up they would stop
and not get carried away by ultimate glory. But im sure 2000 scientists
together have figured that out.
ANSWER:
The goal is purely
intellectual, that is knowledge for its own sake which, in my opinion,
is one of the defining characterstics of humankind. But, most knowledge
eventually will lead to applications someday; who would have guessed 200
years ago that electricity would have ever been more than a curiosity?
that someday horses would be purely for recreation? Regarding your
second question, it is likely that the energy will be gradually ramped
up as they start using the collider because that is the best way to
troubleshoot a new accelerator. It is absolutely not because anybody
thinks this could "rip apart the universe" the energy is called high
energy because the particles go very fast (just less than the speed of
light) so, given their size, they have very high energy. But in an
absolute sense, the amount of energy any particle has is really tiny,
not nearly enough, for example, to warm your cup of coffee.
QUESTION:
I THINK I understand that, in the "twins paradox"
experiment, that the space traveler ages more slowly only during the
period of acceleration; once she reaches the experimental speed (whether
its 60%c or 80%c), then - as long as she's travelling in a straight line
at a constant speed, she ages the same as her twin on earth. Is this
correct?
ANSWER:
Most elementary modern physics textbooks
explain the twin paradox as all the aging taking place during the
noninertial (accelerating) phase of the trip. I consider this to be
totally incorrect and a complete copout! One need introduce no general
relativity to understand the twin paradox, the period of acceleration
can be made infinetesmally short. I have previously outlined how to
think about the twin paradox and you should read that; note that there
is a big difference between how fast clocks run and how fast they appear
to run to other observers.
QUESTION:
I recently read that all
matter within a black hole gets compressed to a singularity where matter
no longer exists. How can you have mass without matter?
ANSWER:
I think that what is meant here is that the mass is not in the form
which we normally associate with matter, e.g. solid, liquid, gas... But
mass has a much more specific definition. There are two kinds of mass
but they turn out to be the same (which is explained in the theory of
general relativity). One is gravitational mass: it creates and feels
gravitational fields and a black hole certainly fulfils this criterion.
The other is inertial mass: it causes an objece to resist acceleration
if a force is applied to it, also certainly a property of black holes.
QUESTION:
Hello, I just wanted to know if there are any gases that
exist that are very good electrical conductors, but do not respond to
magnetism. Plasmas conduct electricity, are there any types of plasma
that do not respond to even strong magnetic fields?
ANSWER:
Any
moving electric charge experiences a magnetic force when in a magnetic
field and any unionized gas is, in itself, a poor conductor. Therefore,
the answer to your question is no.
QUESTION:
the air contains
approximately 0.03% of carbon dioxide and this amount is almost
constant.why is this so?
ANSWER:
Why is it almost constant or why
is it 0.03%? Much of the reason that CO2 is fairly low is that plants
absorb it from the atmosphere and give off oxygen. Therefore, the
northern hemisphere has a slightly higher amount than the southern
hemisphere because the amount of landmass is greater in the north. Also,
the level fluctuates seasonally because of the winter dormancy of many
green plants. Recently, as you probably know, the levels have been
steadily increasing because of people and their cars, factories, power
plants, etc.
QUESTION:
I read about Cerenkov radiation and the
"blue glow" that it causes. Is this glow always blue? If not, does it
depend on what the medium is (water, oil, etc.) or what the particle
traveling faster than light is?
ANSWER:
The intensity of the
radiation is proportional to the frequency. Therefore, the higher the
frequency (shorter the wavelength) the more intense the radiation (the
spectrum is continuous, not of a single wavelength). Therefore, it turns
out that most of the "light" is in the ultraviolet spectrum. You would
therefore think that Cerenkov radiation should look purple, but the eye
is more sensitive to blue so that is what we perceive. For the same
reason (sensitivity of the eye) the sky is blue and not purple.
QUESTION:
How can i plot the function Sin[n pi/2]/(n pi/2)
ANSWER:
This is just basically the function sin(x)/x. All you need
to do is take your calculator and, for several values of x, calculate
sin(x), divide it by x, and plot. You can make your correspondence to n
by n=2x/p. The only problem point is at x=0; here you have to find the
limit as x approaches zero. It may be shown that sin(x)/x=1 for x=0. The
curve looks like the figure to the right.
QUESTION:
Could microwaves, 95GHz 3mm wavelength, be focussed on a tiny point
using lens or mirrors ?
ANSWER:
Yes, any electromagnetic wave is
susceptible to focusing using reflection or refraction provided that you
design your mirrors and lenses to work with the wavelength you are
working with. You cannot use the same lenses and mirrors that you would
use for visible light.
QUESTION:
Let m0 be the rest mass of a
photon. Since it moves with the velocity of light, its energy is, E= m0
c2----------(1) This means that m0 = E/ c2 ---------(2) By Einstein’s
Theory of relativity, m0 = 0 Hence, from (2) E/ c2 =0, Or, c=1/0 How is
this possible?
ANSWER:
Your basic premise, the expression for
energy, is wrong. The energy is given by E=(p2c2+m02c4)1/2 where p is
the momentum. Since the rest mass of a photon is zero, E=pc which tells
you the relationship between energy and momentum for a massless
particle. The energy of the photon is also given by E=hf where h is
Planck's constant and f is the frequency of the corresponding
electromagnetic wave.
QUESTION:
I'm an editor for Scuba Diving
magazine, and I wanted to check something that one of our writers
included in an article about how to save air when scuba diving. One of
his tips is "Swim Slowly," and here is his explanation of why you should
do so ...
"Water is dense and, unlike air, not compressible. To swim
through it, you have to force aside your bodyąs volume and (assuming
youąre neutrally buoyant) your weight in water every time you move
forward the length of your body. (Imagine if you had to shove aside a
200-pound sack of sand to walk six feet.) Obviously, the faster you
swim, the more body-weights of water you have to move aside in a minute,
and the more energy and air you consume to do it. The energy cost of
speed is even more than you might think because itąs an exponential
function proportional to the square of the speed. So swimming twice as
fast requires four times as much energy and air. But the reverse is
true, too: Swim half as fast as you do now, and youąll use only
one-fourth as much air."
ANSWER:
As we all know, it certainly
requires more effort to swim through water than to "swim" through air.
However, this has little to do with the compressibility of the fluids
and it is also not accurate to say that you are pushing the water out of
the way. The reason is almost entirely due to frictional type forces and
these turn out to be determined by the viscosity of the fluid (it would
be harder yet to swim through honey, but its density is close to that of
water). It also depends on velocity and geometry. The author is correct
that the force which the water exerts on you depends on the velocity;
for some velocities, fluids, and geometrical situations, this dependence
is approximately proportional to the speed squared as the author states.
Now, to swim through water with a constant speed requires energy; the
amount of energy is the force you must exert (equal and opposite to the
force the fluid exerts on you) times the distance you swim. Assuming
that the amount of air you consume is proportional to the work you do,
then yes it does require less air to swim some distance slowly.
QUESTION:
which is hotter and which is colder in water- black or
white construction paper, and why?
ANSWER:
You have not given
enough information for your question to be answered. If you have a
completely isolated system in thermal equilibrium, everything will be
the same temperature. If you have two objects, one black and one white,
in a very large amount of water (so that its temperature is constant)
being illuminated by light, the black will absorb more of the light and
the energy of this light shows up as an increased temperature. The white
will also absorb light but not as much so it will not get as much hotter
(like something black in the sun gets hotter than something white). The
water will be more efficient at carrying off this heat and so the
temperature difference will not be as large as in air.
QUESTION:
I'm curious about the wavelength and frequency of light and if either
relates to its speed, and if so, how? If I were to setup a laser motion
detector (such as ones often used in small mini-marts to ring an
electronic bell when a customer enters or leaves) and it were to operate
using infared (800nm to 1m wavelength) versus if I used ultraviolet
(<248nm?) and I was able to find something that moved incredibly fast in
an attempt to move through the beam of light without triggering the bell
which would I have a better chance with?
ANSWER:
There is a very
simple relationship among speed (v), frequency (f), and wavelength (l)
of a wave: v=fl. Furthermore, the speed of electromagnetic radiation, be
it visible light, infrared, ultraviolet, is a universal constant
(actually, it is speed of waves in a vacuum which is constant for all
waves but air is virtually indistinguishable from a vacuum as far as
light goes). So all light should perform the same as far as timing is
concerned. However, there will be some dependence on the wavelength
depending on what you are detecting; a person would absorb or reflect
visible light far better than radio waves, for example.
QUESTION:
if their is a truck full of birds and the birds are sitting at the
bottom of a trailer ,does it weigh the same as if all the birds are
flying?
ANSWER:
There is more than one answer to this question.
Let us assume that the birds are hovering or moving with constant
velocities. In that case, each bird stays in flight because the air
exerts a force up on him equal to the bird's weight; but Newton's third
law requires that the bird therefore exerts an equal downward force on
the air. Therefore the net weight of the whole truck is unchanged. All
forces internal to a system cancel out in the calculation of the net
force on that system because of Newton's third law. Another possibility
would be if the birds have an acceleration with a vertical component;
the simplest example is that all the birds are in freefall inside
(probably not what you had in mind by "flying") in which case the birds
would not contribute to the weight (neglecting any air friction or
buoyancy). A similar question was answered earlier which might interest
you.
QUESTION:
my 10 yr old son aked me the following question
over the weekend and I have no idea if the answer can ever be known -
but here goes:- If the universe started with a big bang and has been
expanding ever since - then in the second before the big bang - where
did all the matter come from?
ANSWER:
I believe that it is not
understood where the energy of the universe came from.
QUESTION:
I'm a martial artist debating an old concept in martial arts that I find
to be dubious in terms of the physics. Suppose I punch a heavy bag that
is initially at rest. Prior to hitting the bag I have generated some
momentum. At impact, my arm and body will be decelerated by the reaction
force from the bag. The theory is that if I keep my rear foot flat on
the ground and have a solid body connection from that foot to the
punching hand, the ground now "supports" my punch and it will therefore
have more effect on the target. This is often called "hitting with the
ground". My suspicion is that this explanation is not quite correct.
Among the confusion is that I'm not a passive object, I can continue to
apply some force during impact by continuing to drive off the back foot,
but I suspect this results in more of an added "push" due to the
extended time interval of contact, and what I really want is the biggest
impulse. I need the help of a real physicist. Does "grounding" the
reaction force of a punch through my body to the ground give the punch
more power, or does it just matter how much momentum I can generate
prior to impact?
ANSWER:
In introductory physics courses we
usually talk about momentum in terms of collisions of point masses.
Here, since the various parts of your body move with different speeds,
this is not quite true. But, let's think in terms of a perfect point
mass M being your whole body moving toward the target with some
effective speed V so that you have a momentum MV. Now, for simplicity,
assume a perfectly inelastic collision and assume the target has the
same mass as you do (which seems reasonable since martial arts are for
fighting other folks). Then momentum conservation has MV=2MV' where V'
is the speed of the two of you immediately after the collision. Hence,
V'=V/2. The force which your opponent (and you) feels is the time rate
of change of his momentum, that is approximately MV/(2T) where T is the
time the collision lasted, so one way to increase the force is to
minimize the duration of the punch. So, now let's get to your question.
If you keep a foot in contact with the floor what you are doing is
increasing your effective mass (the whole earth now becomes part of the
system). This increases the momentum which will, in turn, increase the
force applied (if T stays the same). This is a very simplistic overview
but gives you the flavor of what is going on.
QUESTION:
Taking
the light as a guiding agent (its invariant speed) in several thought
experiments,the lorentz transformation of coordinates can possibly be
completely derived,and time dilation, lenght contraction,non
synchronisation of simultaneous events,and such things can be understood
therefrom.But mass increase seems to be detached from this continuity of
explanations. The explanation of "Mass" gets carried away by referring
to Sir J.J thompsons electron experiments. Hence the question arises- Is
it possible to deduce the effect of mass increase ("Mass increases by
gamma factor as velocity increases"{where gamma=(1-(v/c)2)-0.5}by purely
referring to lorentz transformations?without referring to explanations
and definitions from electromagnetism. The relativistic addition of
velocities seems to provide some clue. Also an explanation as to how the
time part of four momentum can be treated as energy is needed.
ANSWER:
All the quantities which you can derive from the Lorentz
transformation are what we call kinematic quantities. Mass, force, and
more importantly linear momentum and energy are what we call dynamic
properties. So, just like in an introductory physics course where, after
we learn how to describe motion (kinematics), we next want to understand
how motion can be changed; in classical physics this leads us to
Newton's laws. What happens in relativistic physics is that we quickly
find that Newton's second law, in the form F=ma is no longer a true law
of physics; that is, if two observers both measure the acceleration of a
mass m they will get different answers for a, so that would mean that
force is no longer a useful concept in that context. So what we do is
look for the relativistic equivalent of Newton's laws. To do this, write
Newton's second law as F=dp/dt where p=mu is the linear momentum and u
is the velocity of the particle, so for an isolated system we expect to
find dp/dt=0, that is the momentum is conserved. If mu is the definition
of momentum, where m is what classical physicists call the inertial
mass, we find that momentum conservation is no longer a true thing for
isolated systems. So, what we do is to redefine what we mean by momentum
such that momentum is conserved and the new definition becomes the old
definition for small speeds. If we define momentum as p=gmu we find that
momentum is conserved in an isolated system and p≈mu for small u. So,
you see, the gamma factor comes from redefinition of momentum, not
redefinition of mass. Almost all introductory physics texts say that it
is mass which increases, and this is certainly a possible
interperatation of the new definition of momentum. I prefer to say that
m is the inertial mass of an object at rest and that p=gmu. Your
question about energy being the fourth component of four momentum is too
involved for this site.
QUESTION:
Is ball lightning real or hype
? If real, how is it formed ?
ANSWER:
It is real. How it is
formed is, I had thought, not very well understood. However, I did find
a news story from 2002 which says the mystery is solved.
QUESTION:
I'm a fifth grade teacher. A text for my students about butterflies says
that the morpho butterfly, which has a blue appearance, actually isn't
blue. Rather, when light is reflected off the edges of its scales, the
wings appear blue. I have heard this line of reasoning with children
before, from a park ranger, explaining to my students that a bluejay
isn't blue either; rather, it's the light reflecting off the wings that
makes it appear blue. My understanding of color is that this very
reflection of light IS color, and that you may as well say that nothing
really has any color, but rather, objects have properties that allow us
to perceive color once light hits them. Who's naive here, me, or the
book and the park ranger?
ANSWER:
Anything has color by virtue of
the wavelength of light which comes from it. Our eyes can detect the
color of the light and it is that which defines something's color.
Perhaps we should be careful in our definition of the color of
something: it is the color which we see when the object is illuminated
with white light (which, as I am sure you know, is a mixture of all
visible colors). I do this so we do not have to confuse the discussion
with, for example, a white object which is illuminated by green light
and therefore is green; let's just say it's white. So, what determines
what wavelength (color) of light comes from something which is
illuminated with white light? The most common mechanism is that the
object absorbs light of some wavelengths but not so much others. So, if
my wall has a paint which absorbs much of the light which is not red but
doesn't absorb red very well, then my wall is red. But there is another
very important way which nature has found (many butterflies, birds like
peacocks and hummingbirds with iridescent appearances, etc.), and it is
called interference. Have you ever noticed the pretty colors on a thin
film of oil floating on water (like a parking lot after a rainfall), or
on a soap bubble? What is happening here is that light reflects from
both the front and back of the film and goes back to you. If those two
waves happen to emerge in phase (that is the peaks and valleys of the
light occur at the same time and same place) they add up to be very
bright in that color but other colors will not add constructively and
can even completely vanish if the peaks of one coincide with the valleys
of the other. Although biologically it is more complicated than this
(the interference comes from something called a diffraction grating
formed by the "scales"), the general reason is still similar to thin
film interference. If you want more detail, google interference
butterflies or check out this link.
QUESTION:
If an asymmetrical
object, say a spaceship shaped like a "7" in its dorsal perspective had
an engine assembly like a booster of some type attached to that
left-hand arm at its furthest point or very close to it, how much force
in relation to the forward force would be needed to compensate for the
drifting that would occur due to that forward momentum being produced by
the engine being so far out? I ask because I am an Artist who enjoys
(you guessed it, SciFi and Space travel)...I have designed an ship that
is very asymmetrical, with the main drive being positioned practically
on the farside of the rest of the ship being held away at a distance. So
I was thinking of using a thruster assembly for a compensator, but I
feel it would be better if there was some actual thought on this one.
ANSWER:
When a force is exerted on an object two things can happen:
(1) there will be an acceleration of the center of mass of the object in
the direction of the force. And (2) there will be an angular
acceleration about the center of mass of the object and in the direction
of the torque (that is the object will begin spinning about its center
of mass). What you would want in a spaceship is to get the first but not
the second. Yes, you could put another little "thruster" a large
distance from the center of mass to have an equal and opposite torque,
but that would be impractical since I presume you want the main engine
to be very powerful so, unless you could put a small engine very far
out, it would not have adequate torque. What you should do if you insist
on this configuration is to point the main engine so that the direction
of the force it exerts passes through the center of mass and would
therefore exert no torque; this would probably be not terribly off what
you might call "straight ahead" since the main engine is likely to have
a very large mass and the center of mass would therefore be relatively
close to it.
QUESTION:
I'm a med student working in the neonatal
ICU. The attending and I were debating over this physics problem.... So
when the babies can't eat on their own (not strong enough to suck) we
put a tube in their stomachs and put the nutrition in for them. Usually
the 30mL of food per feed is put into an open syringe (ie. no plug)
which is connected to the thin tube going into the stomach. HE says that
the speed at which the food goes in is dependand on the height of the
syringe more than anything else. I said that this isnt' true (though I
just discovered on Wikipedia that it would be if it were a syphon type
system) and I think its more dependant on the length of the tube, the
diameter and the viscosity of the fluid. However, I cant prove this
mathematically. Could you help answer this question?
ANSWER:
Your
friend is partly right if you are dealing with an ideal fluid like most
introductory physics texts deal with. But you are the winner for real
fluids. Imagine sending water through your apparatus; then, with
everything about the experiment being identical, repeat it with honey.
Surely your colleague would not argue that the times would be the same.
Indeed, you would still have a good arguing point even with an ideal
fluid: surely the fluid will leak out a large hole faster than the small
hole.
QUESTION:
What seems like a very simple concept to me is
something a friend of mine can't understand. Could you explain this in a
way he might be able to comprehend? Car A is travelling along a road at
20m/s. Car B is 20m behind car A and doing 22m/s. Car C is travelling at
1000m/s. Car D is 20m behind car C doing 1002m/s. Will the time taken
for A to catch B equal the time taken for C to catch D? I believe the
answer to this question is yes.
ANSWER:
The important concept to
understand here is called relative velocity. If you drive down the
street at a speed of 40 mi/hr and another car comes toward you with a
speed of 40 mi/hr, then you see it approach you with a speed of 80
mi/hr. Thus, if two cars start out at opposite ends of a football field
each going 40 mi/hr, they will crash at the same time as if one had
stayed put and the other approached going 80 mi/hr. They will not crash
at the same place, and maybe this is what is confusing your friend. If
the cars are traveling in the same direction, as in your examples, you
subtract the speeds to get the relative speed. The directions of all the
speeds can be taken care of by using vectors, but it is probably better
to just use your common sense if you are trying to get a feeling for it.
For example, if you are going 40 and the car in front of you is going
42, he is moving away from you with speed 2; if he is going 38, he is
moving toward you with speed 2 and you will collide if you don't slow
down. So what matters is the relative velocity. In the specific examples
you state, if the two pairs of cars start simultaneously an equal
distance apart, say 10 miles, the two chasers catch up at the same time.
They will not, however, have gone the same distances before catching up
as in my example above.
QUESTION:
I am a biologist who regularly
uses chemiluminescence to expose x-ray film. During my distant days as a
chemistry student, I was oriented to the theories that energy and light
are transmitted as waves or packets. From one perspective, sound is
merely a lower energy/lower frequency than light. Can you help me answer
the two following questions: 1.Can one consider radioative emmisions
(i.e. from 32-P) as merely waves with very very high frequency? 2. X-ray
film depends on a chemical reaction for it to be exposed. This reaction
requires energy from a source. Visable light, UV light, IR light, and
radioisotopes all produce enough energy to expose the film. Can I cause
the film to be exposed with high frequency audible sound of long
duration?
ANSWER:
First, sound is not just lower frequency wave
light waves because light is electromagnetic radiation which travels in
a vacuum; sound is a disturbance in the air or other material media and
cannot travel in a vacuum. There normally are three kinds of
radiaocative emissions and one of them, gamma-radiation, is merely very
energetic electromagnetic radiation. I am not very expert at x-ray film
but I believe that it occurs via the photoelectric effect, that is one
quantum of the x-ray is completely absorbed and causes the chemistry to
occur. So presumably x-ray film is sensitive to a narrow band of
frequencies of electromagnetic radiation and less energetic photons
would not expose the film. Sound waves are not quantized and so cannot
cause the chemistry to happen no matter how loud it is or how long you
"shout at it". (Actually, sound is sometimes quantized inside crystal
and the quanta are called phonons.) So if some important chemical
interaction requires a threshhold amount of energy to cause it to
happen, no radiation with less energy per photon will be detected and
sound will not be detected either.
QUESTION:
Well this may seem
dumb, but no one can answer it, no one can say why this is so? X2+Y2=
the square root of Z2 Why is this so? I had the hypotheses that it was
related to the base number system, but the conclusion was false. X3+Y3=
the three square roots of Z3 or rather Z*Z*Z But it did not work.
Proposition One, the hypotenuse cannot be greater than the opposite and
adjacent sides added together, neither can it be shorter than the
longest line, this logical, needing no proof, Yet the space between is
in question in Proposition One, X3+Y3= Z3 this does not transgress
Proposition One, Nor does this X^N+Y^N= Z^N Z = the hypotheses, N equals
the power of the base system number. Proposition Two, Therefore we can
infer Proposition One with the equation above, which is X^N+Y^N= Z^N, to
conclude this equation does not transgress Proposition One. Therefore
why is space defined with the 2=N? To simplify, two products of
themselves what is the root of them? Why Is this so? Proposition three,
space could have been defined in another universe, as N=1.25, or N =
3.1, why in this universe N=2? Given the equation X^N+Y^N= Z^N. Are my
Proposition correct, I think so, but why is it the power of 2 in a base
system, and not for say the power of 3 in a base system. Why is this
universal equation X2+Y2= Z2 to space? any help would be nice?
ANSWER:
Well, this is not really a well-focused single question, but
I will try to answer it. This is really a mathematics, not physics,
question. The Pythagorean theorem is true for Euclidean geometry, that
geometry in which we seem to live, the geometry which we learn in high
school. There are hundreds of proofs which you can use to refresh
yourself. It has nothing to do with the number system we use to count
with. An example of someplace where the theorem is not true is on the
surface of a sphere. Imagine two lines starting at the north pole which
are 900 apart and they run down to the equator and the equator then
completes the triangle; Then all three sides are equal. Although you
seem to think that it is not true that X3+Y3=Z3, that equation can be
true; given X and Y you may find Z to satisfy the equation. For example,
if X=1 and Y=2 then Z=(9)1/3. What is particularly interesting about the
Pythagorean theorem is that there are special cases where X, Y, and Z
are all integers greater than zero, e.g. (3,4,5) and infinitely many
others. One of the most famous of mathematics' unproved conjectures was
known as Fermat's last theorem (1637) which states that there are no
solutions where X, Y, and Z are positive integers greater than zero to
the equation XN+YN=ZN with N>2. It was only recently (1995) that the
proof was achieved by Andrew Wiles.
QUESTION:
i dont know how
reliable a source this is, but i recently watched the movie "what the
bleep do we know" and it talked about electrons and how they jump in and
out, between places. it then mentioned that the nucleus of an atom does
a similar thing, popping in and out. i'm not sure if i misunderstood. is
the nucleus constant?
ANSWER:
I really don't know what you are
asking. It probably refers to vacuum polarization where the presence of
an electromagnetic field causes virtual electron-positron pairs to
appear and disappear spontaneously. There is nothing wrong with this as
long as it happens quickly enough that the uncertainty principle is not
violated; that is, it is ok to violate energy conservation as long as
you only do so for a very short time. Similarly, any
particle/antiparticle pair could appear and disappear. Since both nuclei
and electrons are electrically charged, this can happen near either of
them. It does not mean that the electron or nucleus are popping in and
out of existence, just the "clothing" in the vacuum around it.
QUESTION:
How likely is it that the laws of nature will change,
making life in the universe impossible, say within 1000 years, 1 million
years, and 1 billion years?
ANSWER:
Since there is no evidence
that the laws of physics change at all, there is no chance based on what
we know. It is of interest to astrophysicists to look for evidence that
the fundamental constants of nature might change, but there is no firm
evidence of its happening. In any case, it certainly will not happen
within less than a million years.
QUESTION:
at what pressure and
temperature will carbon melt instead of sublimate?
ANSWER:
See
the attached phase diagram.
QUESTION:
I was wondering, is it
possible for electrons and protons to annialate each other? Even though
an electron is an elementary particle and a proton a baryon?
ANSWER:
No, it is not possible. If it were the universe would become empty of
mass.
QUESTION:
Do Newton's Three laws relate to each other?
ANSWER:
I don't really understand what you are asking. The three of
them together form the basis of the dynamics and statics of classical
mechanics, and they are therefore related in that they all address the
same types of problems. On the other hand if you are asking if one can
be expressed in terms of another, that is if they are in some way
redundant, the answer is no. Although many people write off the first
law as simply a special case of the second law, that is not correct and
each of the three conveys unique ideas.
QUESTION:
I'm currently
in an argument with a few friends, some of which are in engineering
whether gravity and the idea's surrounding it are covered as the Theory
of Gravity or the Law of Gravity. I've been lead to believe that it is
the Theory of Gravity and as such it is concidered a law merely because
it has been around for so long. However, it is still JUST A THEORY. Now
if I'm wrong I'll recant and apologise to them. So, is it the Theory of
Gravity or the Law of Gravity. And do you have any links or references
that I could use to either prove or disprove it either way?
ANSWER:
I would say that it depends on how you define a law and a theory. Here
are my definitions: a law is a mathematical statement describing how
something is whereas a theory is an explanation of why something is.
Now, I assume that you are referring to Newton's universal law of
gravitation, namely F=-Gm1m2/r2. This is an empirical law that tells you
the force which two objects exert on each other because of the
gravitationsl attraction; it says nothing about what the origin of this
force is, that is why do two objects which have mass attract each other.
I would therefore say that this is not a theory of gravity, it is a law
of physics. On the other hand, the theory of general relativity explains
why two masses attract each other (because the presence of mass "warps"
the space around it} and therefore is the operative theory of gravity. I
should point out that either a law or a theory might be applicable only
in special circumstances; for example, Newton's three laws of motion are
applicable in everyday life but when you try to extend them to very
large speeds or very small distances, they become inapplicable.
QUESTION:
;
while seeing from the ground the towards the sky, the
long distant flight emits smoke and the trail of smoke behind looks like
a cloud, like a rocket is going. Why is it so.
ANSWER:
The
condensation trail left behind jet aircrafts are called contrails.
Contrails form when hot humid air from jet exhaust mixes with
environmental air of low vapor pressure and low temperature. Because of
the high altitudes, contrails are composed of ice crystals and become
cirrus clouds.The mixing is a result of turbulence generated by the
engine exhaust. Cloud formation by a mixing process is similar to the
cloud you see when you exhale and "see your breath".
QUESTION:
If I shoot a modern arrow straight up into the air with a bow that
exerts 75 lbs of thrust does the arrow travel to the top of it's flight
in the same amount of time that it takes to fall back to earth?
ANSWER:
A freshman physics class would say yes but that is if you
neglect air friction. On the way up the arrow has two forces on it: its
weight down and the air friction also down. On the way down it also has
two forces on it: its weight down and the air friction up. The problem
is complicated somewhat by the fact that the air friction force depends
on velocity, so it is not possible, without stipulations on the initial
speed and the details of the air friction to determine which will be
quicker, up or down, but since the forces on them are definitely
different if there is any air friction at all, the times will definitely
differ.
.
QUESTION:
What is the efect of the shape and the
thickness of the slit in a single slit diffraction?
ANSWER:
By
"thickness" I presume that you mean the width of the slit. This is part
of the standard single slit analysis and it is found, as the slitt gets
narrower the pattern expands. The shape also determines the nature of
the pattern. The simplest (extreme) example would be the pattern from a
hole. An example is shown at the right.
QUESTION:
My question
relates to the double slit experiment. It is my understanding that when
photons are "shot" one at a time through a double slit, the screen
records individual dots - the pattern of which (over time) will be
"striped" (i.e. consistent with a diffraction/interference pattern).
Hopefully what I just said is correct? Anyway, my question is: what
happens if only one single photon is shot (i.e. there is no stream of
photons)...is there an inteference pattern on the screen with this one
photon, or does the photon appear as a dot in the spot on the screen
where one would expect it to be based solely on the particle theory? In
a general sense, my question is whether the interference patterns arises
from previous photons interfering with later ones rather than one
particular photon intefering with itself? A related question is what
happens if a stream of photons is shot but there is a "significant" time
delay (not sure what time frame) between shooting each photo n...i.e.
does the interference pattern disappear in this case (assuming this expt
is technically feasible)?
ANSWER:
You will see a dot from a
single photon. However, it will retain some of the properties of the
diffraction pattern. E.g. it will not fall where the dark stripes would
be for this double slit and it will not (necessarily) pass straight
through like a simple particle would. It is far better to think of the
photon interfering with itself rather than other photons. Indeed, the
kind of experiment you refer to ("one at a time") is the same as that
you allude to at the end, that is you can shoot photons through at a
rate of one per hour and the diffraction pattern will still be there.
QUESTION:
if atoms can "last" for about 1035 years, what happens to
them? do they just cease to exist?
ANSWER:
This is not a fact but
speculation. It has been proposed that protons, along with electrons the
stable components of matter in the universe, will ultimately decay.
Nuclei are composed of neutrons and protons and a free neutron decays to
a proton, an electron, and a neutrino. The most likely proton decays
ultimately end up as two photons and a positron. The positron then finds
an electron and they annihilate to two more photons. Other decay modes
include neutrinos also. So what happens is that when all the atoms
disintegrate the universe will be filled with photons and neutrinos. I
must emphasize that this has never been observed even though large,
elaborate experiments have been done to try to see proton decay. The
"standard model" of elementary particle physics does not predict proton
decay, that is the proton is stable in that model.
QUESTION:
if
a penny is placed on a rotating turntable, where on the turn table does
the penny require the largest centripital force to stay in place?
ANSWER:
The centripetal force is given by mv2/R where v is the
speed, m is the mass, and R is the radius of the circle in which it is
moving. The speed of an object which is on a rotating rigid body (your
turntable in this case) is v=Rw where w is the angular speed (in
radians/s). Since w is a constant (every point on the turntable has the
same rotational speed), the centripetal force is mR2w2/R=mRw2. So the
force increases linearly with the radius, so the answer to your question
is the force is greatest on the extreme edge of the turntable.
QUESTION:
if I have the amount of momentum an object has how can I
convert that to the amount of potential/kinetic energy the object has
ANSWER:
The kinetic energy is p2/(2m) where p is linear momentum and
m is the mass of the object. There is no general relationship between
the momentum and potential energy; however, in cases where total energy
is conserved, as the kinetic energy decreases the momentum will decrease
and the potential energy will increase. So, for systems where energy is
conserved, you may write E=p2/(2m)+V where E is total energy and V is
potential energy. You can now solve this equation for p.
QUESTION:
How do I make a guitar out of scratch? My Physics class needs to
construct an instrument out of scratch and I don't know where to start.
Can you help me?
ANSWER:
A guitar which demonstrates the
principles should be fairly straightforward to make. Probably not too
good for making music though. I would start by getting one guitar string
and stretch it between two nails on a board; it would also be good if
you made there be a way you could vary the tension, as the peg does in a
guitar. This is a rudimentary stringed instrument. You can demonstrate
that a plucked string makes sound and that the frequency (pitch) of that
sound gets higher as the tension in the string gets higher (how a guitar
is tuned). But the sound will be very small. That is what the box of the
guitar does--it resonates and thus greatly amplifies the sound of the
vibrating string. So get a box, wooden and closed on all six sides. cut
a circular hole in one side and stretch your string across the hole; it
would be best if the nails you strung the string between were actually
in the box. It would also be good if the wood was not too heavy so that
the wood itself can vibrate to contribute to the sound. I have seen this
kind of thing done with a wooden cigar box.
QUESTION:
What light
source will bounce/refract/reflect off of broken glass? Will regular
light, a laser, or some other source. Let's assume it is clear glass
ANSWER:
Any electromagnetic radiation, and so any light, when it
strikes an interface between two media (for example air and glass) will
do two things: it will refracted into the material and it will be
reflected from the interface. The only exception is called complete
internal reflection where light inside glass, for example, strikes an
interface with a material with smaller index of refraction with a
grazing enough angle; it will reflect only, not leave the glass. This is
how fiber optics works. But that does not seem to be your question and
there will always be some light of any wavelength reflected from glass
in air.l
QUESTION:
How is it possible to explain the movement of
light with respect to its particle nature? that particle will reach
infinite mass due to the theory of relativity.
ANSWER:
Actually,
the theory of relativity predicts that any particle of zero mass must
travel at the speed of light. Photons are such particle. Until recently
it was thought that neutrinos were massless but we now know that they
have a tiny mass. Although a graviton has never been observed, it is
believed that it travels with the speed of light. A particle with a
nonzero mass takes infinite energy to accelerate to the speed of light,
but photons have no mass and so take no energy to accelerate to the
speed of light since they are already there.
QUESTION:
what math
equaion can i use to find PSI of water at diffrent hights.
ANSWER:
You want to calculate the pressure at a depth d in a large body of
water. The appropriate equation is P=PA+rgd where PA=105 N/m2 is
atmospheric pressure, g=9.8 m/s2 is the acceleration due to gavity, and
r=1000 kg/m2 is the density of water. A N/m2 is called a Pascal (Pa). On
the other hand, you might want to compute the guage pressure which is
the amount above atmospheric pressure in which case PG=rgd; your tire
pressures are measured in guage pressure. Let's calculate an example.
Suppose you are 10 m down. PG=1000x9.8x10=9.8x104 N/m2=9.8x104/6895=14.2
PSI. Note that I have used the conversion 1 PSI=6895 Pa.
QUESTION:
Is there any heat associated with visible light? I know heat is usually
in the IR range, but is there any heat in the visible range? If so, how
much and or is it measurable? For example, when using a 100 watt halogen
light bulb that when turned on produces enough heat to melt wax. How
much heat is IR vs Visible Light?
ANSWER:
Radiant "heat" energy
usually means energy which arrives via infrared electromagnetic waves.
However, there is not really a precise definition. All electromagnetic
energy delivers energy to whatever it is absorbed by, determined by the
intensity. The reason that IR is usually called radiant heat is of
biological origin: we are mostly water and water absorbs IR radiation
very efficiently. So, if IR and visible light, each with the same
intensity, strike you, more of the IR is absorbed.
QUESTION:
A
piece of ferromagnetic material having mass m is rolled under a
permanent magnet suspended above. When it gets close enough, it's pulled
up against the magnet, rising by a height h. The total work done is
therefore mgh (g = acceleration due to gravity). Where did the amount of
energy mgh come from?
ANSWER:
This seeming simple question is a
quite difficult and subtle one. Since the explanation is too lengthy to
give here, I am giving you a link here where you can study the details.
Essentially, this is Faraday's law in action: when the ferromagnetic
material gets magnetized it is equivalent to a current loop; when a
current loop moves in an nonuniform magnetic field an electric field is
induced; this electric field does the work.
QUESTION:
Assuming
the speed of light is constant--light emitted from the front of a
motorcycle at rest will travel at the same speed as light from a moving
motorcycle. This means that if the motorcycle travels down a road with a
light mounted perpendicular to the motorcycle that the light being
emitted will not gain the motion of hte motorcycle, that is motion
perpendicular to the motion of the direction the light is emitted will
not by in anyway added to form a resultant direction and motion of the
light emitted. Are the above statements correct? If not why? If yes,
does this mean that the absolute motion of the earth can be found by
emitting lasers tangent to its surface and measuring the difference from
the expected path?
ANSWER:
As soon as you start having velocities
which are not along the line of motion, it gets more complicated. If you
have a component of the velocity perpendicular to the direction of
motion, the velocity seen by a "stationary" will be affected by time
dilation but not by length contraction. Hence, the transformation for
the transverse (perpendicular) and longitudinal (parallel) components of
velocity are different. If you are really interested, you can get a
discussion here. The amazing thing is that the speed of light still
comes out to be the same, but the direction is altered; that is, if the
light is emitted perpendicular to the direction of travel, the velocity
seen by a stationary observer is in a direction different from
perpendicular but still of the same speed. It does "gain the motion of
the motorcycle" but loses just the right transverse velocity so that the
speed stays the same.
QUESTION:
What work is being done while
you walk? I say the floor is doing work on you since the the floor is
exerting a forward force and your direction of travel is in the same
direction. Is this correct?
ANSWER:
Walking is a pretty
complicated thing because it is a periodic series of accelerations and
decelerations. If we look at the time averaged situation there is a
constant velocity and therefore, since the kinetic energy is not
changing, no work is being done. You are correct that the external force
which does work in the short term, either speeding you up or slowing
your down, is the frictional force between the floor and your feet.
QUESTION:
Do carbon nanotubes burn in vaccum? like in space?
ANSWER:
Nothing burns in a vacuum. Oxygen is required for burning.
COMMENT FROM A READER:
I noticed one wrong answer - a simple
miswording, most likely. It was asked if carbon nanotubes would burn in
a vacuum, and the answer was that nothing burns in a vacuum. This is
better worded as nothing burns without oxygen, as some molecules are
self-oxidizing, or can burn without a vapor atmosphere as long as an
oxidizer is present.
QUESTION:
Do electrons move slower in a
colder environment, like air molecules move slower in a colder
environment, if not why?
ANSWER:
Yes. An important concept in
physics is that of an electron gas; this provides a good model for
valence electrons in a conductor since the valence electrons are
essentially free to move. And the average speed of the electrons
deterrmines the temperature of a gas just like in any other gas.
QUESTION:
You have a muon, which is a fundamental particle(a
fermion) like an electron, whose mass lies between an electron and
proton. It's lifetime is approximately 2.2 micro seconds. It then decays
into a neutrino and antineutrino. My question is this. Since neutrinos
have at best an extremely tiny mass, surely an antineutrino and a
neutrino's combined mass does not equal the mass of the muon. So where
does this extra mass go when a muon decays?
ANSWER:
For
starters, you have it wrong regarding the decay. A muon is either
postively or negatively charged and the neutrino or antineutrino is
uncharged; therefore the decay mode you assume would violate charge
conservation. The most common decay of a negative (positive) muon is
m-®e-ne*nm (m+®e+nenm* ) where an asterisk indicates an antineutrino. So
you get one electron (positron), one neutrino, and one antineutrion. But
your question is still pertinent: where did the missing mass go? There
is no law that mass must be conserved (in spite of what was postulated
by 18th century chemists!) What must be conserved is total energy.
Although in recent years it has been discovered that neutrinos have a
small mass, it is so incredibly small that I may neglect it in this
discussion. What must be conserved is energy and mass is a form of
energy. Thus, assuming that the muon which decays is at rest (not
necessary), the energy before the decay is Mc2 where M is the mass of
the muon; after the decay the energy is mc2+T where m is the electron
(or positron) and T is the summed kinetic energies of the three decay
products. We then equate energies before and after to conserve energy.
So the missing mass shows up as kinetic energy. Since Mc2>mc2, it is not
possible for all the decay products to be at rest after the decay.
QUESTION:
;
If a radio signal is bounced off an object that is
directly above the sending or receiving station, the signal strength is
stronger at the receiver than if it bounces off an object that is midway
between the two stations. I have been able to confirm this phenomenon in
several books, but they all fail to explain WHY. I tried to figure it
out with optics, but was unsuccessful.
ANSWER:
Since radio
signals fall off roughly like 1/r2 (r is how far it travels) I thought
that this would be a relatively simple problem of calculating the
distance of the path of each and finding that the over the transmitter
path was shorter. However, choosing the height as 10 and the ground
distance as 500 (units are unimportant for qualitative understanding), I
found that the stronger at the receiver situation had a longer path
(about 510) than the weaker at the receiver situation (about 500). So
that ain't it! Next, the plane is not a perfect reflector, so maybe that
has something to do with it. I now calculated, assuming a loss of half
the signal upon reflection (and still 10 and 500 distances), the
following two scenarios: (I will call the intensity at the transmitter
I.)
For the plane directly over the receiver, the intensity it sees
I/100 and the reflected intensity is I/200. Now, that signal must travel
a distance of (102+5002)1/2, very close to 500. So the final intensity
is (I/200)(1/5002)=2x10-8I.For the other situation, the intensity at the
plane is I/(102+2502)=1.6x10-5I and the reflected intensity is 0.8x10-5I
. Now, the distance to the receiver is (102+2502)1/2, very close to 250.
So the final intensity is (0.8x10-5)(1/2502)I=1.28x10-10I, substantially
smaller.So, I surmise, the reason is the fact that a much larger signal
eminates from the plane when it is close to the transmitter.
CORRECTED ANSWER:
It has been pointed out to me that my calculations
above would have arrived at exactly the same conclusion without the loss
of half the signal upon reflection. In fact, that is completely right:
just multiply both answers by 2 for 100% reflection and the conclusion
is still the same! So, it has nothing to do with the reflectivity of the
plane but rather with the strength of the signal at the time of
reflection. I stand corrected!
QUESTION:
Why is there no sonic
boom from light or radio transmissions?
ANSWER:
A shock wave
(sonic boom in the case of sound) happens if the source of the waves is
moving faster than the waves themselves. Another example of a shock wave
is the wake of a boat if the boat moves faster than the water waves.
Light and radio are electromagnetic waves, not their sources. If you had
a light source moving faster than the speed of light, there would be a
"lumen boom". However, as you probably, nothing can go faster than the
speed of light in a vacuum. However, light travels more slowly in a
material, for example glass or water; then if a particle travels faster
than that light speed, shock waves occur. This is often seen in the
water surrounding a nuclear reactor since energetic subatomic particles
passing through the water are moving faster than the speed of light in
water; it is seen as a blue glow.
QUESTION:
If I have two
cylinders, one with an inside cross sectional area 2 square inches, and
the other with an inside cross sectional area of 1 square inch; each
cylinder has an airtight piston with an attached handle; each cylinder
is the same length; and each cylinder has a nozzle with an inside
diameter of .5 inches; which cylinder will suck up more water with the
nozzle if an equal amount of force is exerted on the handle? And what
are the laws of physics that would govern this situation?
ANSWER:
You need the continuity equation and Bernoulli's equation to do this. I
find it easier to think about the fluid moving the other way which is
equivalent, so that is how I will do it. I will use the following
notations: at the the nozzle the speed of the fluid is v2, the cross
sectional area is A2, and the pressure is P2; at the piston the speed of
the fluid is v1, the cross sectional area is A1, and the pressure is P1.
The pressures are P1=PA+F/A1 and P2=PA where PA is atmospheric pressure
and F is the force applied. The continuity equation states A1v1=A2v2;
this simply says that the rate of fluid in is the same as the rate out.
So, you may solve for v2 which is not of interest to us: v2=A1v1/A2.
Now, Bernoulli's equation says that P1+rv12/2=P2+rv22/2 where r is the
density of the fluid. (This is not the most general form; if the nozzle
and were at significantly different altitudes y then there would be a
rgy term added to each side of the equation.) Now, if you do all the
algebra you will find that v22=2FA12/[(A12-A22)r]. One important thing
to note is that if A1 is much greater than A2 the speed out is
independent of A2: v2@2F/r. For your cases, A2=.5, A1=1, and A'1=2
(units are not important since the areas enter as ratios), then v22=2.67
F/r and v'22=2.13 F/r so the thinner piston moves fluid through the
nozzle faster.
QUESTION:
If I drive slowly on my dirt road it
rattles my teeth. If I drive fast it feels better. What's best for the
suspension of my truck (and my teeth)? Driving fast or slow?
ANSWER:
If you have a bump and go over it you experience an acceleration and
Newton's second law says there must be a force causing the acceleration.
The faster you hit the leading edge of the bump the greater the
acceleration, so the greater is the force you feel. This is basically
how speed bumps work, However, if there is a series of small bumps
relatively close together the inertial of your car might carry you from
one to the other so that you do not have to go up the leading edge.
Also, since your springs are relatively stiff, a high bumping frequency
has the wheels bouncing but the car (and you) not moving as much whereas
at a slower speed the car and wheels and you move more as one. I guess
my rambling says you should go faster (as long as you can maintain
control).
QUESTION:
Is it possible the reason why Electrons do
not fall into the nucleus is; the closer an Electron gets to the nucleus
it's charge is diminished, or it begins to become more positive and
repelled? 2nd, the reason why it does not fly away from the nucleus is;
the farther away it gets from the nucleus, it becomes more Negatively
charged?
ANSWER:
Your suggestions are not possible. One of the
most sacrosanct of all physical laws is conservation of electric charge.
The charge of an electron never changes under any circumstances.
QUESTION:
I have a question that no one seems to be able to answer.
If mass can be converted to energy at the speed of light, under what
condition(s) can energy be converted to mass? I am trying to imagine
what the inverse of the speed of light might be.
ANSWER:
I do not
know what you mean by "converted to energy at the speed of light"' or
"the inverse of the speed of light"; let's just say that mass may be
converted into energy. I take it your question is then "under what
condition(s) can energy be converted to mass?" Well, any condition you
like provided that rules like charge conservation, energy (including
mass energy) conservation, and momentum conservation are obeyed. Here is
one example: the nucleus of an atom has a mass smaller than the sum of
its parts (neutrons and protons). If you now disassemble the nucleus you
will, of course, have to add energy (that is, do work) which shows up as
increased mass of the system. Note that the inverse is also true, that
is if you take a bunch of neutrons and protons and push them together
you will get a net gain of energy by creating the final nuceus; this is
how stars work.
QUESTION:
Is it possible to create elements like
gold or titanium in the nuclear fission/fussion reactor? Is it likely
that we would be able to create at least a few atoms of it sometime in
the future?
ANSWER:
Not only is it possible, it happens all the
time. By definition, a fusion or fission nuclear reaction starts with
fuel and turns it into something else. In the case of fission, take
uranium, for example. When it fissions, it splits into two nuclei. Those
that you give as examples, gold or titanium, are unlikely (not
impossible) because the distribution of fission products tends to fall
mostly between rubidium and gadolinium (see Wikepedia for more detail).
For fusion, we get the sum of the fusing nuclei, for example hydrogen
plus hydrogen fuses to helium, helium plus carbon fuses to oxygen, etc.
Inasmuch as the early universe was all hydrogen, the very existence of
other elements today proves that they were created (in stars) via
fusion.
QUESTION:
I am interested in determining the amount of
friction (and subsequently heat) generated in primitive friction fires.
I have read about calculating coefficients for static and dynamic
friction, and am wondering if there is another formula that is more
applicable. The fire-making method I have in mind involves the rotation
of a wooden dowel (with a rounded tip, like a half-sphere) in a wooden
socket with a corresponding half-spherical shape. I would like to be
able to compare the amounts of friction for various wood species, and
use that information to determine how much heat can be generated with a
given diameter dowel. Any help would be greatly appreciated.
ANSWER:
Friction is a very tricky thing. In its simplest form, the frictional
force, which will determine the heating rate, is proportional to the
normal force (how hard the two are pressed together. In your case,
however, the temperature varies and so the proportionality constant
(coefficient of friction) will not be a constant at all but vary with
the temperature. Physics is not just a theoretical science but equally
an experimental science. In a situation like yours, the best way to
study this problem is to do experiments.
QUESTION:
Are there
places in an atom, where the electrons are located, that make it more
likely that electrons will form bonds?
ANSWER:
I am not sure what
you are asking. The electrons most involved in chemical properties of
atoms are the valence electrons which are generally the outermost
electrons.
QUESTION:
Why does light get dimmer as it gets
farther away?
ANSWER:
If you have a source which is radiating in
all directions, like a light bulb, then if you get a distance from it
which is large compared to the size of the filament, then, as you say,
the light gets dimmer as you get farther away. That is because light
carries energy and that energy gets spread out over a larger and larger
area as you get farther away. The intensity of light is defined as the
energy crossing a square meter in a second and that gets smaller, of
course, as the available energy spreads out. Not all light gets dimmer
as you go away: a laser is light which does not spread out but stays in
its narrow beam, so the spreading is very small so the intensity is very
nearly constant as you go farther away. Laser beams have been shot to
the moon, reflected back, and lose very little intensity.
QUESTION:
do have more than one point free of electrical filed in a square with 4
charges at its edges
ANSWER:
I assume you mean equal charges.
Field will also be zero infinitely far away.
QUESTION:
Of what
matter is moon made of ?
ANSWER:
See
http://www.nasm.si.edu/exhibitions/cchoice/moonrocks/moonrocks1.htm
QUESTION:
I have heard that cold can eventually "seep" through
anything, no matter what it is made of. I was wondering if this is
correct.
ANSWER:
"Cold" is a qualitative concept and it is
meaningless to ask if "it" can "seep". If you have two objects with
different temperatures, then energy will be transferred from the higher
temperature to the lower temperature until equilibrium is reached (equal
temperatures); this will happen regardless of what is between them
(provided that it is an isolated system) since there is no perfect
insulator. The energy transfer, if there is a vacuum between them, will
be accomplished via radiation.
QUESTION:
Please tell me if you
know how to separate water into gasses with electricity or any other way
for that matter. - I would like the most to know how to do it at home
and possible safe one too, but anything is better tan none so please
give me any info that you can on this topic.
ANSWER:
Check out
http://www.reachoutmichigan.org/funexperiments/agesubject/lessons/energy/split_h2o.html
QUESTION:
I was watching the science channel today and was learning
about the theory of dark matter. I had a fundamental issue with this
idea because it simply places a unknown into an equation that satisfies
the answer which we expect/is projected based upon our own understanding
of physics. This idea simply seems too easy a solution. I began thinking
about quantum physics of which I know little to nothing about. What I do
know is that quantum physics is necessary because the laws of physics
which apply to our daily life at human scale do not apply to that of
subatomic particles. The show was trying to explain the reasoning behind
galactic rotation. The show stated in order for galaxies to rotate at a
uniform speed from their inside to their outside without the galaxy
destroying itself there must be necessary unseen mass(Dark Matter). My
question is why if on a small anatomic scale physics is altered making
mass behave differently wouldn't it also, on a much larger scale
relative to daily human life, make particles also act in a completely
unique form of physics? I was wondering this because although it is a
generally baseless theory the idea would make dark matter totally
unnecessary.
ANSWER:
Most astronomers and astrophysicists
seemingly have no problem postulating the existence of dark matter to
explain many observations which seem to indicate its presence. However
others, like myself, find this to be sort of akin to the postulation of
the "luminiferous aether" postulated to provide a medium through which
light waves could propogate. What you are suggesting is, in fact, quite
reasonable: until we can test with precision that our laws of nature are
the same at very large distances, it is somewhat presumptive to assume
that they must be. I should warn you, however, that most mainstream
astrophysicists would not be in agreement with this point of view.
QUESTION:
If the earth suddenly shrinks to half of its present
radius, the acceleration due to gravity will be what?and why?
ANSWER:
Assuming that the mass remains the same, the gravitational
force, and thus the acceleration due to that force, would increase by a
factor of 4 because the gravitational force is inversely proportional to
the square of the distance from the center.
QUESTION:
What is
the temperature of fire?
ANSWER:
It depends on many things, like
what is burning, what the environment is like, etc. Typical temperatures
are around 1500o C. A little more detail on different kinds of fires may
be found on Wikepedia.
QUESTION:
Is it possible for a
helicopter to hover above the Earth and have the Earth move under as it
rotates so that the helicopter would "travel" around the Earth in 24
hours?
ANSWER:
Inasmuch as the earth drags its atmosphere with
it, the helicopter would have to travel at a speed much larger than
helicopters go relative to the air to remain in the same position in
space as you stipulate. So, no it is not possible.
QUESTION:
What happens to the atomic number and mass number of a nucleus when it
emit (a) a positron? (b) a gamma ray?
ANSWER:
charge decreases by
one unit, so atomic number decreases by one; mass number stays the
same.mass number and atomic number are both unchanged
QUESTION:
I am
a 9th grade student currently attending Nelson County High School in
Kentucky. The other day i learned in physics class that light travels
slower through glass than it does through air. Does this mean that light
travels slower through matter of lower energy?
ANSWER:
Light in a
vacuum is the fastest thing in the universe. Light traveling through any
medium is therefore slower. The fact that light travels more slowly
through a medium like glass is why lenses work. I do not understand what
you mean by "matter of lower energy".
QUESTION:
Will carbon
molecules hold an electric charge, i.e. could carbon be magnetised?
ANSWER:
Don't know just what you mean. Yes, you can make a C
negative ion, that is add an electron to it. However, this has nothing
to do with its being "magnetised". I think what you must mean is can you
make carbon ferromagnetic. The answer is no since ferromagnetism depends
on the crystaline structure of the material and the interaction of the
outermost electrons with their neighbors, and it is most unlikely that
you could make carbon do this. All materials are "magnetised" in some
sense, either paramagnetic (attracted to a bar magnet) or diamagnetic
(repelled); the effects are much weaker than ferromagnetism.
QUESTION:
If there are four fundamental forces--gravity, EM, weak
and strong--how does the Casimir force fit in this scheme?
ANSWER:
The Casimir force has its origins in the electromagnetic force (vacuum
fluctuations of the electromagnetic field). You can read a nice
discussion at Physicsweb.org.
QUESTION:
If one were to release a
standard, 20 lb., 8.5 x 11 inch sheet of white copy paper from, say, the
space station, with adequate velocity to exit orbit and fall toward
earth. Could it survive the trip? I seem to be the only one to believe
that it could. The strongest claims against this theory so far have been
meteorological- perhaps it becomes soaked with water, etc. what do you
rhink?
ANSWER:
The possibility of water causing shoul not even be
considered since, obviously, passing through a good thunderstorm could
certainly cause the paper to go to pieces. The situation would depend on
the speed at which the paper was moving when it hit the top of the
atmosphere. For example if you just "dropped" it, that is caused it to
fall straight down (which would actually mean giving it a velocity of
about 18,000 mi/hr opposite the shuttle, I would guess it would make it
since it would hit the atmosphere with a relatively small velocity. On
the other hand, if you released it with just slightly less speed than
the shuttle has but enough less to leave orbit, my guess is that when it
hit the top of the atmosphere that it would "burn up" and be destroyed.
QUESTION:
i've noticed many similarities between gravitational
fields and electric fields. Is there an analog in electricity to a black
hole?, an infinite electric field with infinite charge at a point? If
not, why not? If so, what sort of physical reproductions does (or would)
this have on surrounding matter?
ANSWER:
The answer is no because
a black hole forms because the gravitational force is attractive and so
as you add more and more mass to an object it eventually collapses under
the huge gravitational force (this is a bit of an oversimplification,
but essentially how a black hole forms). The electrical force, however,
is repulsive, so you the more charge you add the more the object wants
to fly apart.
QUESTION:
is it possible to trap light in a box if
it were filled with mirrors? and since things have color because of
light ( ex.blue things reflect blue light and absorb all the others)
when there is no light is everything actually invisible?
ANSWER:
Light would be trapped only for a very short time after which it would
be absorbed by the mirrors (heating them up slightly); there is no such
thing as a perfect mirror. For some numbers showing how quickly the
light would disappear, see one of my previous answers. Regarding your
second question, if you define "visible" as being able to be seen by the
human eye, then, yes, things are invisible if there is no light.
QUESTION:
If the sun were to disappear in an instant, would the
Earth spin off into space IN DARKNESS?? or would the "final light" from
the sun, taking some 7-plus minutes to reach Earth, arrive prior to the
"release" of magnetic pull/gravity occurrence as experienced on/by
Earth? Perhaps my question has to do with the nature of gravitational
pull--is it a "chain/rope"-sort of essence or some sort of wave, which
would, I think, have to be at or less than the speed of light and means
the light would go out first. I find my uninformed bias is toward the
"rope" form, in which case we would by leaving orbit while the sun was
still shining on Earth.
ANSWER:
The speed at which a
gravitational field propogates has not, to my knowledge, been measured.
It is generally believed that it propogates at the speed of light. Thus,
the earth would leave orbit and go dark simultaneously. In any case, no
physicist would believe that the appearance of any force would be
instantaneous.
QUESTION:
Heres a physics question... I have a
rubber band and three toothpicks. I loop the rubber band around two of
the toothpicks, and hold them apart, stretching the rubber band. I have
someone hold the two end toothpicks. I then slip the 3rd toothpick in
the dead center of the rubber band, and start twisting it, winding the
rubber band from the center. Then, I let go of the center toothpick, at
the same time as my buddy lets go of ONE of the end toothpicks. The
third toothpick is still held firm. The question is: Which toothpick
spins faster, the center one or the end one. And more importantly, WHY?
What physical theory causes this?
ANSWER:
First, since the the
speeds will depend on when you look at them, let us revise your question
so that we ask which will have the biggest acceleration at the start,
that is which will acquire the greatest speed in the first short time.
Your question is equivalent, at the beginning, to masses on springs. The
middle toothpick is analogous to a mass attached to two identical
springs, each stretched by some amount. The end toothpick is analogous
to the same mass but attached to one spring stretched by the same
amount. So when you first release them, the one with two springs has the
greater acceleration. This will only be true immediately after release
because the half of the rubber band between the two movable toothpicks
will untwist faster.
QUESTION:
If you built a machine that would
swing a weight and "kick" a ball along the ground, controlling all the
variables, excepting that you double the weight, why would the distance
the ball travel only be 30% more?
ANSWER:
You have not given me
enough information about the machine, but a little consideration of the
answer leads me to think that the machine must simply be the head-on
elastic collision between two balls of different masses, one initially
at rest. If the "kicker" has a mass M and incoming speed V, and the ball
has a mass m and is at rest, then if you conserve both momentum and
kinetic energy you will find the ball, after the collision, has a speed
v'=2mV/(M+m). So, let us do two numerical examples:
If M=m, then
v'=V.If M=2m, then v'=(4/3)V.Guess that answers your question since the
distance the ball travels (while experiencing a constant retarding
frictional force) is proportional to the initial speed.
QUESTION:
In the acoustic doppler effect, i have found that the higher the
original frequency, the greater the shift in frequency.
ANSWER:
Quite simply it is because the frequency difference is proportional to
the original frequency. In terms of a percentage change, there is no
dependence on frequency.
QUESTION:
Does a hockey puck reach it's
maximum velocity at the last instant of contact with the hockey stick,
or is there such a thing as (for lack of the proper terminology)
'residual acceleration' I have considered this at great length.. >From
what I know in physics if there is no longer force being applied to the
puck there should not be any accelertion after the contact.... Almost a
logical deduction.. however seeing replays and it's almost an instinct
telling me that I might be wrong.. It doesn't feel like the stick is
travelling at a the same velocity as the puck is.. 100mph shots and
all.. Perception maybe different than reality.. anyway, if I am wrong
and there the puck continues to accelerate for a short distance after
leaving the stick,. it's because of the flex in the stick, the energy
transfered into the puck has not fully caused it to accelerate..
possibly like the flex in a golf ball..
ANSWER:
A short answer
to your long
QUESTION:
The puck cannot continue to accelerate (gain
speed) after it leaves the stick. In the physics sense, it does
accelerate but with a negative acceleration, that is it slows down.
QUESTION:
my question is how is the current flowing through the
different resistors connected in series same f it is an axiom, then its
ok. but if it has reason behind it,pls tell me
ANSWER:
No, it is
not simply axiomatic. The reason is the conservation of electric charge.
Consider just two resistors connected in series. A certain amount of
electric charge enters one resistor in a certain time (electric
current). Similarly, a certain amount of charge exits the other
resistor. If the charge out is less (greater) than the charge in, where
is the charge going to (coming from)? Electric charge cannot be created
or destroyed, and since it is not piling up or being drawn from either
resistor, the charge in must equal the charge out so the current in each
is the same.
QUESTION:
I've always wondered if "time" is a
man-made concept or if it really exists. I've heard that the fourth
dimension is time, is this true?
ANSWER:
This is more a
philosophy than physics question. As a physicist, I would say that time
exists independent of my perceiving it. Our intuitive notions of time,
such as that time is a universal thing throughout the universe for all
observers is now known to be incorrect. Two identical clocks given to
two different observers will definitely not run at the same rates if the
observers are moving with respect to each other. This is the unavoidable
consequence of the theory of special relativity. Time is the fourth
dimension in the sense that when it is realized that time and space are
entangled with each other, the result again of special relativity, the
mathematics of the physics involving both space and time is very similar
to the mathematics of a four dimensional space. For example, motion in
three space may be described as a rotation in four space.
QUESTION:
A 50cm silver bar becomes shorter by 1mm when cooled.How much was it
cooled? coeff. of linear expn=.000018/c. Which should be my original
length ? 50cm or (50-0.1)cm?
ANSWER:
The equation you use,
presumably, is DL=aDT=a(Tf-Ti)=(Lf-Li). Since Tf<Ti you must have Lf<Li
so Li=50 cm.
QUESTION:
My cousin and I have a dispute about the
flushing power of a standard 1.6 gallon flush toilet, versus an
old-fashioned 5-gallon flush model. I use a lot of toilet paper, and
therefore must flush 2 or 3 times with the newer 1.6 gallon models, or
risk a clog, which has happened to me far too often. I maintain that the
5-gallon flush model will be much more likely to prevent clogs. Is there
a formula for computing the pressure of a 1.6 gallon flush versus a 5.0
gallon flush? How would that be mathematically computed with precision?
ANSWER:
There is no reasonable way to compare them mathematically
since they have different designs. The low usage one is supposed to be
designed to have comparable disposal capabilities. Even if you are right
that you, as an individual, must flush more than once, from a
conservation point of view it would still be better to have an efficient
toilet because you are likely not the only user. My son uses way too
much paper also and every once and a while it clogs; I just pull out the
old plumber's helper and in no time all is well.
QUESTION:
Hello, I have solved this question part of the way, but cannot figure
out the end result! The question is: In an x-ray imaging system
operating at 70 kVp, each electron arrives at the target with a maximum
kinetic energy of 70 keV. Because there are 1.6 x 10^-16J per 1keV, this
energy is equivalent to the following: (70keV)(1.6 x 10^-16J/keV)=1.12 x
10-14 J Inserting this energy into the expression for kinetic energy and
solving for the velocity of the electrons, the result is: KE=1/2mv2
v2=2KE/m v2=(2)(1.12 x 10-14 J)/(9.1 x 10-31 kg) =0.25 x 1017 m2/s2 I
can get that far....the end result is: v = 1.6 x 108 m/s If i use the
equation v= mv2, I get: v = (0.25 x 1017) (0.25 x 1017)2 which gives me
- v=(0.25 x 1017)(0.063 x 1034) and my answer comes out to v = 1.6 X
1051 m/s How do they get the answer v = 1.6 x 108 m/s ?
ANSWER:
This looks like a homework problem which the groundrules of my site
prohibit! However, I will give you the hint you need: your expression
KE=mv2/2 is wrong; this expression is true only for very slow (compared
to the speed of light) particles. The correct expression is KE=E-moc2
where E is the total energy, mo is the rest mass, and c is the speed of
light. E is given by E=(mo2c4+p2c2)1/2 where p is the linear momentum
given by mov/(1-v2/c2)1/2. Also, your equation v=mv2 is obviously
incorrect because it could be simplified to mv=1 which is nonsense!
QUESTION:
My 11 year old has asked me, "Does gravity bend light?" I
did highschool physics about 20 years ago, so am very rusty and not up
to date with current thought. I have looked at this discussion topic on
the archives of many forums, but have ended up very confused by the
differing opinions/explanations. I would really like an answer which is
easy to explain to a child, but yet not so simplistic that it is
inaccurate. Am I asking the impossible? She has read about the nature of
light and also about gravity, and can't understand how light can be
affected by gravity, when it has no mass. Is it because photons are
energy and so can be used instead of mass? Or is it that the
gravitational pull around massive stars affects the "space" around it
and light just follows the stretched paths? If this is true, how can
some authors say that the light is still moving in a straight line even
when it is following a curved path?
ANSWER:
Here is one
explanation, probably the easiest for your daughter to understand: Light
being affected by gravity is a result of the principle of equivalence in
general relativity. This states that there is no experiment which you
can perform to distinguish between your being in a gravitational field
or in an accelerated frame of reference. Thus, for example, imagine that
you are in an elevator which accelerates upward; if light enters through
a hole in the side of the elevator it will clearly appear to fall like a
projectile because of the acceleration of the elevator. So, the same
thing will appear to happen in a gravitational field the acceleration
due to which is exactly the same as the acceleration of the
elevator. Hence, light will "fall" in the earth's gravitational field
with an acceleration of 9.8 m/s2. You might be interested in the answer
to an earlier question.
Here is another: If we look at the world as
having a Euclidean "flat" geometry and watch a ray of light pass a very
massive object, we see the light bend. But, the way that general
relativity describes the world says that, if we are in the vicinity of a
massive object the space itself is not Euclidean but is curved; in this
space the light follows a "straight line" in that non-Euclidean
geometry.
QUESTION:
what is error on T when T = 1.04 * sin (2.8
± 0.2)/ sin (58.2 ± 0.2)
ANSWER:
The largest contributor to the
error will be the sine in the numerator since sine is small and changing
rapidly at small angles so a relatively small uncertainty in the angle
will lead to a large uncertainty in the sine of the angle. You can get a
rough feeling for the percentage of the uncertainty by estimating the
percent error of that term: (sin2.8-sin2.6)/sin2.8=0.071=7.1%. What you
need to know is that the uncertainty of the sin(A±a) is approximately
cos(A)*a (because d[sin(x)]={d[sin(x)]/dx}dx) and that the percent
uncertainty of a ratio (A±a)/(B±b) is approximately a/A-b/B. Putting
your numbers in I get about 6.7% (in accord with our rough estimate)
uncertainty for T, or about ±0.004. {When you are doing your
calculations it is important that angles (and their uncertainties) are
expressed in radians, not degrees.}
QUESTION:
Does the flow of
linear time as we percieve it (disregarding its pyschological
variations) vary as you get down to the level of quantum mechanics?
Secondly, if so, I've read at that level, all time is simultanteous,
that it doesn't exist at all at that level. Is this true, and why?
ANSWER:
The answer to your question is that we do not know. Read my
earlier comments related to this question. Regarding your second
question, I never have heard it said that "all time is simultanteous"
whatever that means. I have read that it is the opinion of some very
deep thinkers that the reason that not much progress has been made in
unifying gravity and quantum physics is that we really do not understand
time very well.
QUESTION:
how is it possible that light can be
both a particle and a wave! i need to know it's ruining my whole life.
ANSWER:
Ruining your whole life? How is it possible that my tie can
be both red and green? That is just the way it is. I know that this is
an unsatisfying answer, but science is based an measurements
(experiments) and if you study light and look for a wave, you will find
one but if you look for a particle you will find that also. This is
called the wave/particle duality and it is, essentially, a statement of
experimental fact. And you can do experiments which unambiguously see
both possibilities in the same experiment. The best known example is to
do a double slit experiment with very low intensity. If the intensity is
so low that there is, say only 1 photon per minute passing through, then
it has to pass through one slit or the other, right? Wrong--you still
get an interference pattern. So, you say, light is therefore a wave, not
a particle. But, imagine that the screen detects the light using the
photoelectric effect which cannot be understood unless you treat the
light as a collection of photons. This detector will work perfectly well
in displaying the interference pattern. This duality is not unique to
light: any particle will exhibit wave properties; e.g. that is how an
electron microscope works, by exploiting the wave properties of
electrons. Maybe I shouldn't have told you this since it may compound
your life-ruining distress! Wave/particle duality is a reality of
nature, that is all.
QUESTION:
A sample of a particular
radioisotope is placed near a Geiger couinter, which is observed to
register 160 counts per minute. Eight hours later, the detector counts
at a rate of 10 counts per minute. What is the half-life of the
material?
ANSWER:
This sounds suspiciously like a homework
problem to me! However, I will outline how to do it but not do it to its
final answer. The activity of a sample (counts rate) is an exponential
function: A(t)=A0exp(-lt) where A(t) is the activity at time t and l is
the decay constant related to the halflife by t=ln(2)/l. Since you know
A at two times (I would call the first one t=0), this equation is
actually two equations for two unknowns (A0 and l), so you can solve for
l which gives you t.
QUESTION:
WHEN A 1,000 POUND PLANE HAS
WINGS THAT ARE BANKED AT 45* DURING A LEVEL TURN, THE CENTRIPETAL FORCE
ON THE PLANE IS EQUAL TO THE WEIGHT OF THE PLANE. USE THE PYTHAGOREAN
THEOREM TO FIND THE LOAD ON THE PLANE. [LOAD=WEIGHT+(CENTRIPETAL FORCE)]
A. ABOUT 2,000 POUNDS
B. ABOUT 707 POUNDS
C. ABOUT 1,414
POUNDS
D. ABOUT 500 POUNDS
ANSWER:
This looks suspiciously
like a homework problem to me which are forbidden by the groundrules.
However, it is sort of interesting to me because it doesn't make a lot
of sense. I would have thought that load would be defined as the net
force on the plane. However, load is defined here to be the horizontal
component of the force the air exerts on the plane plus the weight
(which is, of course, vertical). This force has a magnitude of the
square root of 10002+10002, so C is the answer with the direction
pointing 450 below horizontal. If the load were the force the air exerts
on the plane, the answer would still have a magnitude of 1414 lb but
would be in a direction 450 above horizontal. If the load were the net
force on the plane the answer would be 1000 lb horizontal.
QUESTION:
Does the wavelength of light affect how brightly it
shines?
ANSWER:
No, "brightly" is determined by the amplitude of
the wave and not by its wavelength.
QUESTION:
What is light?
ANSWER:
Wow, that is a concise question. The answer is not! The
nature of light has been of great interest over the ages. Once science
became a legitimate pursuit (as separate from philosophy) the debate
centered around whether light is some kind of wave or some kind of
particle. Newton thought it was a particle; it was later demonstrated
(in the early 19th century}, however, that light behaves like a wave;
see my earlier answer to a similar question for more background. What
was actually doing the waving was a mystery until later in the 19th
century when Maxwell showed that light is waving electric and magnetic
fields; again, see my earlier answer. Finally, at the beginning of the
20th century Einstein, in explaining the photoelectric effect, found
that light exists in quantities no less than what is called a photon,
one quantum of the electromagnetic field. Hence, light really is like
particles, a swarm of photons. We finally understand that light is both,
a situation called the wave/particle duality; if you look for a wave you
will find one and if you look for a particle you will find that also.
QUESTION:
do all orbits in space deteriorate? If not, why? Is it
possible that the Earth's orbit could deteriorate (as well as Mars,
etc.) and cause global warming trends?
ANSWER:
For an orbit to
"deterioate" (we usually use decay to describe this), the orbiting
object must lose energy. It can do this by colliding with stuff, mainly
gas and dust so that the energy loss could be thought of like air
friction on earth only much smaller. An orbiting object will also lose
energy by radiating gravitational waves; this has been seen for some
binary star systems. But, for the earth, these are totally negligible
and certainly have no effect on global warming. The distance to the sun
is much less influential than the angle that the rays from the sun hit
us; we are actually farthest from the sun during summer.
QUESTION:
what would happen if there was too much air pressure?
ANSWER:
Well, you don't stipulate what "too much" is, so I will address an
extremely increased pressure. The pressure due to the atmosphere is
about 1 ton per square foot. So why doesn't this pressure crush you? The
reason is that we have evolved in this environment so that the pressure
inside our bodies is about one atmosphere; every cell in your body has a
pressure inside which keeps it from being collapsed. Now suppose that
you double the pressure outside. The pressure inside does not change and
so you are crushed by the net force in on you. One of the first things
to go is your eardrums which should not surprise you if you have ever
dived to the bottom of a swimming pool where pressure increases fairly
dramatically.
QUESTION:
My questions pertain to gravitational
potential energy. Sepcifically, I'm a little confused about how it
works. My understanding is that when an object is moved away from the
earth (upwards) it gains gravitational potential energy that is
transformed to kinetic energy if and when it falls back toward the
earth. This understanding leads me to two questions. First, what happens
to that potential energy once an object moves beyond the gravitational
feild of the earth? Does that object still retain the potential energy
it gained as it moved away from the earth? Second, why must I exert
energy to hold something in a constant position relative to the earth?
for example, why must I exert energy to hold a text book above my head.
It is not moving towards or away from the earth, so is not gaining
potential energy, yet I am exerting energy by holding it up against the
force of gravity. On the other hand, a table does not exert any energy
in accomplishing the same feat. So w hat gives? where does that energy
go? Am I totally off base here?
ANSWER:
Your questions:
An
object in a gravitational field never moves beyond the field since the
strength of the field is proportional to 1/r2 where r is the distance
from the center of the earth. So there is never a place where the field
is zero, just very small. The potential energy you are probably familiar
with is mgy where y is the distance vertically from where you have
chosen y=0. This works fine (but only approxiately) as long as y is much
smaller than the radius of the earth; The correct potential energy is
proportional to -1/r so as r becomes very large the potential energy
goes to zero; but, note the minus sign: the potential energy gets
smaller (more negative) as r gets smaller, so the potential energy
becomes biggest when you are infinitely far away.You are totally
confused about what energy is. The way you impart energy to something is
to do work on it, and work is a force exerted over a distance. You are
exerting a force on the thing you hold over your head, but that force is
not acting over a distance so you are not changing any energy. It makes
no sense, from a physics point of view, to say that you "exert
energy".
QUESTION:
Is it true or not that one can make larger
structures such as planes, spacecraft (rotating) if we make the walls
thicker? Does making the walls thicker enable one to build larger
structures, without making them fall appart or deform?
ANSWER:
There is no answer to this question since what is necessary to make
something bigger depends on what the thing is, what its location is,
what it is made of, etc.
QUESTION:
This may seem like a strange
question and one that cannot be answered without some sort of bias
(religion, etc.), but if energy cannot be created or destroyed, where
does the energy in a living creature go upon death? What other forms of
energy is it transformed into, and what happens to the electrical
signals in the brain and other parts of the nervous system?
ANSWER:
What energy is there in a living being? It is almost all bound up in the
chemicals which make up the body. When it dies, the chemical energy
either stays there or ends up as heat if the object decays. Regarding
the electrical signals, an analogous question would be what happens to
the light coming from a light bulb when you turn off the switch? The
only reason the light bulb continues to glow is that there is a source
of energy pushing electrons through it and when that source is removed
the electric current simply ceases.
QUESTION:
OK, I have a
sealed box with a 60W electrical fan inside. The fan just circulates the
air inside the box. Does this box give off 60W of heat?
ANSWER:
A
60 W appliance is one which consumes 60 W of power, that is it consumes
60 J of energy each second. The appliance then converts this energy to
another form of energy. For example, a toaster will convert most of the
energy to heat (because it is designed to do that). A fan is designed to
not convert energy into heat, but rather into kinetic energy (of both
the fan and the air); the electric motor will heat up but not nearly as
much as a 60 W toaster but probably more than a 60 flourescent light
which is designed to convert as much energy as possible into light. But
if your box is truly isolated from the rest of the world, much of the
energy initially converted into kinetic energy of the air will end up as
heat in the box and its walls.
QUESTION:
What is the
math/calculations to transform volts/meter into newtons/coulomb?
ANSWER:
A volt is a joule/coulomb, 1 V=1 J/C. A joule is 1 kg m2/s2,
so 1 V/m=1 kg m2/s2/m/C=1 kg m/(Cs2).
A Newton is 1 kg m/s2, so 1
N/C=1 kg m/s2/C=1 kg m/(Cs2).
So, 1 V/m=1N/C.
QUESTION:
why
does the d- block in the periodic table have two valence electrons?
ANSWER:
This is really chemistry, not physics. I believe it is due
to the following:
The first 20 elements have s- and p-shells. Beyond
that, the ordering is not what you might expect. For example, you might
expect, after 1s, 2s, 2p, 3s, 3p, are filled that next would come 3d.
However, the 4s happens to have lower energy than the 3d so it fills
first. Therefore, as the nd-shell is filling there are two electrons in
the (n+1)s shell and these have wave functions which extend farther out
than the d-orbitals and thus are more influential in determining the
chemistry.
QUESTION:
How to shield an electronic circuit or
laboratory from stray electric fields, and why does this work?
ANSWER:
Completely surround the circuit with a conductor. The reason
that this works is that the electrons are free to move in a conductor.
When the conductor is put into an electric field, the electrons move
around in the conductor. All such charge (or lack thereof where
electrons have left) will reside on the outside surface of the conductor
and be arranged in such a way that the field due to these "induced"
charges will exactly cancel out the field which induced them inside the
volume enclosed by the conductor. This is called a Faraday cage (named
after Michael Faraday who first constructed one). If what you want to
shield is quite large, just enclosing it with a conducting mesh does a
very good job as well. You should realize that this is true only for
static fields; if the field changes with time, there will be fields
inside the cage.
QUESTION:
If there was no cyntrifical force on
planets... would there still be gravity?
ANSWER:
First of all,
there is no such thing as a centrifugal force; I have repeatedly
discussed that on this site and you can read a bit about it by going to
older answers and searching (do a CTRL F) on centrifugal. The existence
of the force of gravity is universal and the gravitational attraction
between two objects is unaltered by anything else. Gravitational force
between two objects results from their masses and nothing else. What you
may be thinking of is that the apparent force of gravity is lessened
somewhat by the earth's rotation. Imagine standing at the equator: you
have an acceleration pointed toward the center of the earth of v2/R
where v is the tangential speed due to the rotation (2pR/24
hr)=7.3x10-5R and R=6.4x106 m is the radius of the earth. Putting in the
numbers, your acceleration would be a=3.4x10-2 m/s2. A force of ma is
needed to keep you going around in circular motion and the source of
this force is gravity. The result is that your apparent weight, the
weight you read on a scale (which is actually not measuring your weight
but is measuring the force the floor pushes up on you) would be slightly
less than your actual weight. Since weight is mg=9.8m your apparent
weight would be (9.8-0.034)m, about 0.3% less. If the earth rotated
faster on its axis, this effect would be bigger and eventually your
weight would not be sufficient to keep you in your circular motion and
you would drift off into space. But the point is that your weight is
always the same regardless of anything else--gravity is constant.
QUESTION:
how is the stella parallax angle of a distant planet or
star calculated?
ANSWER:
I presume you mean stellar parallax. I
recommend this site for a brief animated tutorial.
QUESTION:
When chemical bonds form, energy is released. Therefore, does water
release energy as heat when it freezes? If yes, does this explain why it
is warmer when it snows? Does the change of water from a gas to a liquid
to a solid cause the ambient temperature to increase?
ANSWER:
You must add energy to melt ice. Therefore you must remove energy to
freeze water. So, yes, water does release energy when it freezes.
Similarly, water vapor releases energy when it condenses. However I
doubt that these effects have any measurable effect on air temperatures.
It is often warmer when it snows because the weather conditions
favorable for snow (clouds, low barometric pressure) cause it to be
warmer; in other words, the warmer (less cold) weather results in snow,
not the other way around.
QUESTION:
While researching I found
out At one time it was proposed to launch satellite directly into a
circular orbit at a constant distant from earth using a giant WW cannon.
Can you pleas tell me why this proposal would not work
ANSWER:
Assuming that we had a cannon capable of launching a projectile with
sufficient speed (at least about 18,000 mi/hr), how would we aim it? One
possibilty is horizontally. In principle, this could work. It was
actually Newton himself who first imagined artificial earth satellites
by proposing shooting a projectile off the top of a high mountain with
sufficient speed. There is a good website where you can play around with
launching satellites; if you set the speed to 16,000 mi/hr you should
see a nice circular orbit. In practice this could not work, however,
because the air friction due to the atmosphere at such a high speed
would either burn the projectile up or cause it to slow down and hit the
ground. If you aimed it up at some angle, the resulting elliptical orbit
would intersect with the surface of the earth, that is it would crash
before one complete orbit was completed. What you need to do is first
lift your satellite above the atmosphere and then give it a horizontal
speed with rockets on the satellite. So a simple projectile will not
work.
QUESTION:
what would happen if a planet identical to Earth
were to lie tangential to the earth, assume that there is no impact
between the two heavenly bodies, one just appears. what would happen to
gravity, the planets, the oceans, etc?
CLARIFICATION:
I meant
that the crusts of both planets would be just barely touching.
ANSWER:
The gravitational field due to two spheres is the vector sum
of the fields of each sphere. Hence, you could easily calculate the
gravitational force at any point in space (in particular, of interest to
you, on the surface of the earth) by just adding the forces due to each
planet. A few simple examples would be:
At the point of contact the
gravitational force would be zero, so if you were located close to this
point you would be weightless.Along a line tangent to both spheres and
passing through the point of contact the force on an object of mass m
(i.e. the weight) would be directed exactly toward the point of contact
and wold have a magnitude of 2GMmd/(d2+R2)3/2 where G is the universal
gravitational constant, d is the distance from the point of contact, R
is the radius of the earth and M is the mass of the earth. Note that
this is zero if d=0 and approximately 2GMm/d2 if d is much larger than
R.At the point opposite the point of contact, the weight of an object
would be have a weight 10/9 times larger than if the new planet were not
there and point vertically down.At other points the weight would not
point vertically down anymore because of the force from the other
planet.To compute these results you need to know that the gravitational
force due to a uniform sphere of mass M on a point mass m a distance r
from the center of the sphere points straight to the center of the
sphere and has magnitude GMm/r2 where G=6.67x10-11 Nm2/kg2 (only true if
you are outside the sphere).
QUESTION:
The core of the earth is
'energized' by the compression of mass, since energy can be neither
created or destroyed, where prior did this energy exist?
ANSWER:
The simple answer to your question is gravity. As a mass decreases in
size its gravitational potential energy decreases and this energy loss
is made up by energy gain, kinetic energy of the mass, that is it gets
hotter. This is also how stars gain enough energy (temperature) to
"ignite", gravitational collapse. It is thought, however, that part of
the energy for heating the earth's core comes from the decay of
radioactive nuclei in the core.
QUESTION:
Further on the "pull
one end of a rope" idea - Do individual elemental particles with mass
behave the same way? That is, do they have a "diameter", such that a
force applied to say, the "right side" of say, a quark, will be "felt"
on the "left side" of the quark an attosecond (or whatever) later?
ANSWER:
You have to be careful in extending classical ideas into the
realm of the very small. In quantum mechanics, the appropriate way to
describe subatomic physics, it turns out that the idea of force is not
very useful. Rather we use the ideas of fields and potential energy. In
classical physics, potential energy is easily related to force
associated with the field. There is no useful way to define left and
right but certainly the propogation of a field, responsible for forces,
is not instantaneous.
QUESTION:
In the article here --
www.iop.org/EJ/article/0143-0807/27/2/017/ejp6_2_017.pdf -- the authors
describe a process whereby sunlight is concentrated using the well known
parabolic dish method, but afterwards is directed into a large sphere
with a completely reflective interior. If one were to direct solar
energy into a sphere of this nature, and closed the "hole", could one
actually "store" the sunlight, and then let it out when needed?
ANSWER:
Well, I find I have no access to that article since I am not
a subscriber to the journal. However, I do not need to see the article
to answer your question. The answer is no, it is not practical to store
light using mirrors. The reason is that a "completely reflective
interior" is simply not possible and the light is quickly absorbed. To
get some idea of the numbers involved, see one of my previous answers.
QUESTION:
In reference to singularities, etc., I do not understand
the concept of "nothing". Since "nothing" is only understood as related
or opposite to "something" it would seem that "something" is primary and
"nothing" is imaginary. "Something" can be shown, while "nothing" can
not be shown except in a relative sense. "Nothing" is only useful in a
limited sense as a technique such as "zero". I think physicists use of
"nothing" shows nonsense. "Nothing" is nonsense in and of itself since
the thought of it alone, vis a vis "something", dissolves from the
imagination. Therefore, the singularity is truly something but as yet
not rationally described.
ANSWER:
I have no idea what your rant
is about. I have never heard a physicist refer to a singularity as
nothing. It has zero size but infinite density (for example if we think
of a model for a black hole). And physicists were the first to realize
that a vacuum is not empty at all but filled with virtual particles
popping into and out of existence (see vacuum polarization). I should
also note that most physicists I know do not believe that a true
mathematical singularity is a physical thing because, although we might
find "nothing" to be unphysical, we find the notion of something being
infinite as abhorrent! However, the use of singularities in models is
extremely useful and helps make our theories comprehensible.
QUESTION:
If I want to create a higher vacuum pressure in a
container, than my vacuum pump can deliver, could I create that vacuum
pressure by placing both the pump and container inside a second larger
container, use the pump to evacuate both containers, seal the larger
container off and then pump out the smaller container once more into the
evacuated larger container. If my understanding of vacuum pumps is
correct, they create a difference in pressure between the inside and
outside of a given space, therefore it should be possible by placing one
evacuated chamber inside another to multiply the pumps capability.
ANSWER:
The way a simple pump works is that it pumps an amount of
air out, compresses it, and expells it. What determines the vacuum
achievable is the rate at which air is leaking in (or outgassing from
inside the vessel) since when you reach the point where the amount you
take out in a cycle equals the amount that leaks in. It is not the
pressure differential which is most important. The catch, however, is
that if the vessel you are evacuating is in a low pressure environment,
less gas will leak in. So my answer is yes and no--how's that for a
hedge?
QUESTION:
Which will travel further when kicked a soccer
ball or an american football. They are roughly the same weight,
410-450grams for a soccer ball and 421 for a football. I am assuming
that the drag caused by the odd shape of the football will cause it to
travel a lesser distance. Is there a way to calculate how much less
either as a distance or percentage?
ANSWER:
This depends on a lot
of things. However, the considerations I have thought of give the
football an edge over a soccer ball. I will assume that each is launched
with the same initial speed and angle. Were there no air drag, it would
surely be a tie. Now, I assume that the football has been punted by a
skilled kicker such that it spirals, that is spins around its lolng axis
of symmetry. When this happens, as you probably know, it goes through
the air pointy end first and is thus more aerodynamic than the spherical
soccer ball. In addition, the soccer ball is relatively smooth whereas
the football is knubbly. Although it is partly nonintuitive, a rough
ball suffers less air resistance than a smooth ball because the rough
surface carries a layer of air along with it called the boundary layer
which helps reduce air friction; this, in fact, is why golf balls have
dimples and tennis balls have fuzz. Finally, I can think of one way the
soccer ball might have an edge: if the ball has a lot of spin in the
right direction, lift will be generated (like in an airplane wing, or
more analogously, a curveball in baseball). I doubt, however, that this
effect will be as large as the effects which make the football go
farther.
QUESTION:
What keeps an electron from crashing into a
proton in an an atom?
ANSWER:
See my answer to an earlier
question.
QUESTION:
If I google "einstein field equations" and
go into the Wikipedia site, the bottem of the first page has "contents."
I proceed to the section "The cosmological constant" and therein find a
version of EFE with Lamda in it. It looks like this: Ruv - 1/2 R g uv +
Lamda (guv) = 8 pi T uv. My question is this: Can I, in a mathematically
valid (algebraic) sense, move every thing except Lamda from the left to
the right side of the equation? More to the point, is it mathematically
valid to say: l=(8 p Tuv + 1/2 R guv -Ruv) /guv I don't know if I'm
breaking any geometric convention. Thank you for your thought.
ANSWER:
No, you may not do this. It is a matrix equation and you
cannot divide by a matrix.
QUESTION:
How can force carriers
affect two particles differently? For example: A virtual photon
interaction between two electrons causes them to repel, but an
interaction between an electron and an up quark causes them to attract.
The photons are the same, so what is different about those two
interactions that can cause different results? (I asked this question on
another website, and I was told only that I was simplifying things too
much. If I'm describing the process poorly, please let me know!)
ANSWER:
You are indeed simplifying things too much. The idea of
particles passing photons back and forth is only a rough schematic
picture of what happens. The particles, quanta, which convey a force
(like photons do for the electromagnetic force) are not real particles
(photons) but rather virtual particles. They are photons which cannot be
directly seen, that is you could not stick a detector between the two
charged particles and be able to detect them. Their existence defies
energy conservation but that is ok as long as they "exist" for a short
enough time; the reason is that it is, according to the uncertainty
principle, ok for DE of energy to appear as long as it disappears within
a time Dt where DEDt is less (approximately) than Planck's constant.
There is a very nice discussion about virtual particles at
http://math.ucr.edu/home/baez/physics/Quantum/virtual_particles.html
QUESTION:
Concerning gravity. I'm very confused (NB I,m 59 yr old
NOT a student!) In a sphere (like a planet) if every atom is fully
surrounded by similar atoms then, except at the surface, shouldn't
gravity effects cancel out? OK, the heavier atoms will 'fall' to the
centre but don't EM effects or the smaller atomic radii of metal atoms
(so they will move through the planets core more easily) explain this?
If centre of planet is a plasma, what does this 'do' to gravity? Has
gravitational force of 'weightless' objects towards each other (eg in a
spaceship) ever been measured? (OK I know it's very weak).
ANSWER:
Whoa, too many questions. The site groundrules state only single,
well-focused questions, but I will go ahead this time and address some
of your questions.
Imagine that you are the atom and you are one mile
deep into the earth. Then if you look "up" you will see many fewer atoms
than if you look down because it is a lot more than one mile through the
whole rest of the earth. So you will still feel a force toward the
center of the earth; it will however, be less than your weight on the
surface. It is easy to calculate the weight of something inside the
earth by the following trick: only that part of the earth inside where
you are exerts a force on you. Hence, if the earth were hollow you would
feel no force inside. Incidentally, your question is related to one of
the most famous problems in the history of science. Newton delayed
publishing his theory of gravitation for years because he could not be
sure that the force between two spheres was the same as the force
between two point masses at their centers. It is a very difficult
problem and part of the reason he had to invent calculus was to solve
this problem. Regarding your second
QUESTION:
heavier atoms do not
preferentially fall toward the center of the earth. If they did then
lead and uranium would be at the core, then lighter and lighter atoms
like onion shells as you went out until the lightest would be on the
surface. This is not how it is. The reason is that all objects,
regardless of their mass move the same way (with the same acceleration)
in a gravitational field. It does not matter what the composition of the
center is as far a gravity is concerned.You do not need to make the
objects weightless to do this experiment. You just have to be careful to
make sure that all other forces on the objects add up to zero. This
experiment has been done many times. The classic experiment was that of
Eötvös (see inset picture) done in the very early 20th century. A group
at the University of Washington has made many modern and very accurate
measurements.
QUESTION:
I have a bunch of lasers and the manuals all
say that the tubes will last longer if they are run a few hours a month.
I used to work in analytical chemistry at an undergraduate lab and the
chemist said that the gas filled tubes for the Atomic Absorption machine
went bad if they weren't run all the time. However, I pulled out a
hollow cathode tube that looked like it had never been used but was in a
box that looked 30 or 40 years old and it was very strong. What is the
physical reason for saying that gas filled tubes last longer if they are
run "A few hours a month"? I have a degree in physics and have asked a
number of PhD phycists and chemists this question and have not received
even an attempt at an answer.
ANSWER: (Courtesy of Chad Fertig)
Running a discharge tube generates pumping action due to sputtering of
the filament. This pumps away (some of the) background gasses that
inevitably leak into the tube. An Ar/Kr Ion laser tube which hasn't been
used in a long while will often need to be run at low-ish current (low
enough to prevent overheating) until the pressure drops and the laser
stabilizes to its normal operating parameters. If the background gas
pressure gets too high, one may not be able to light the tube and not
trip the overcurrent protection circuits. The laser engineers I have
spoken with tell me that the shock of lighting a tube at high-pressure
can be enough to kill the tube entirely. I don't know how much of this
discussion applies to small atomic spectroscopy discharge tubes -- my
experience is mainly with Ar/Kr Ion laser tubes.
ANSWER: (Courtesy of
Uwe Happek)
One should run the laser periodically to activate a
getter pump that traps unwanted aroms that slowly diffuse into the tube.
QUESTION:
If EVERYTHING in the Universe doubled in size...?
.....would anybody notice? What about the square-cube ratio? The surface
area of objects increases by the square, while volume increases by the
cube. If you doubled the diameter of a planet and the height of the man
standing on it, his mass would increase by a factor of eight and the
mass of the planet by a similar factor. So the mans weight would be
something like 64 times as much as before.while the cross section of his
legs would only be 4 times as much. The burden on each square inch of
his legs would be about 16 times the prior burden, without the extra
strength to support it. It would be like suddenly standing on Jupiter.
He would collapse and die very quickly by being 'squashed' to death by
gravity! Obviously this is a purely theoretical question but if the
'known' Laws of Physics were applied to this, what would the answer be?
I may have twisted my knowledge because it has been years since I
studied. Simply take it that the universe has doubled (by magic?! :~} ).
Would there be noticable consequences?
ANSWER:
I would not
presume to make a blanket statement one way or the other for this
question (because we physicists don't deal in magic!) I can, however,
refute your specific example. You have forgotten that the radius of the
earth would double and, since the weight is inversely proportional to
the square of the distance, the weight would be only 16 times greater
(64/4). Hence your new body would be ideally engineered to exist in your
new environment.
QUESTION:
Light is massless and as such is the
only thing can can travel at this speed. For any object with mass, it
would take an infinite amount of energy to reach the speed of light.
Therefore the speed of light is an unattainable goal! However, light can
be caught by a Black Hole (I'm sure you know the phrase - the gravity is
so strong that not even light can escape!). If light is without mass,
how can it be caught by ANY gravity well? Astronomers have also proved
that light 'bends' around black holes in a measurable and observable
way. What can the gravity be 'pulling in' if there is no mass to light?
Am I missing something?
ANSWER:
You are missing
something--classical gravitational theory, where the force is
proportional to the mass, is incorrect. Einstein's general theory of
relativity is a theory of gravity which has withstood all experimental
tests so far. The central idea of this theory is the equivalence
principle which states that there is no experiment you can do by which
you can determine whether you are in a gravitational field or an
accelerating reference frame. For example, suppose that you are inside a
box with no windows and you drop a ball and it accelerates down with an
acceleration g=9.8 m/s2. Are you at the surface of the earth or in the
middle of empty space in a box which is accelerating with an
acceleration g in a direction opposite the direction you see the ball
accelerate? There is no way you can know without looking out a window.
Now do a similar experiment where you stand at one side of the box and
shine a beam of light across the box; it will follow a parabolic
trajectory down if the box is accelerating up, that's for sure (although
for such a small acceleration, it would be very difficult to observe;
see one of my earlier answers). The equivalence principle thus asserts
that the beam of light will "fall" in a gravitational field.
QUESTION:
There is a rope, say 20 mile long, and a person pulls the
rope from one end, point A.
QUESTION:
Will the other end, point B, move
instantly or will it take time?
ANSWER:
It takes time. Basically,
atoms in the rope are held together by the electromagnetic forces
between atoms and electric fields propogate with the speed of light, so
a very rigid strong rope would take a pretty short time for the other
end to start moving. A more stretchable rope would take longer.
QUESTION:
How many tons of TNT would it take to be able to stop an
asteroid with a mass of 7.2e15 kg moving at 2436 m/s? Would we assume
that the collision is ellastic or inellastic and would we use the
priniciples of the conservation of energy or conservation of momentum?
ANSWER:
You are approaching this question in such a way that
there is no way to answer. It depends entirely how the "bomb" of TNT is
configured and is a very complicated question. You can do some
calculations:
the kinetic energy of the asteroid is about 2 x 1022
Jthe linear momentum of the asteroid is about 1.8 x 1019 kg m/sthe
energy content of TNT is about 4 x 109 J/tonProbably the best way to
approach how to stop the asteroid is to consider momentum. The time rate
of change of momentum is equal to the force applied, so suppose you
pushed on the asteroid for a year with a constant force such that it
stopped at the end of the year. Then the force would be
(1.8x1019)/3.2x107)=5.6x1011 N=1.26x1011 lb. The rate at which energy is
expended is the energy change divided by one year,
(2x1022/3.2x107)=6.3x1014 W. This is bigger than the entire energy
consumption rate of the US, about 1013 W.
What you should be
figuring out by now is that it is totally impractical to talk about
stopping this asteroid. When people discuss how to protect us from
collisions from asteroids, the idea is always to make a very small
change in its path a relatively long time before it would hit us. That
means a rather small change in momentum thereby requiring much less
force. For example, suppose you wanted to change this asteroid's
trajectory by 0.010. Then the momentum change would be about
sin(0.01)x1.8x1019=3x1015 kg m/s. If you had an explosion which lasted
10 s, it would have to supply a force of 3x1015/10=3x1014 N=6.7x1014 lb.
This is still a pretty big force, you will agree. Here the energy
increase would be about 6.5x1014 J so the power over the ten seconds
would be 6.3x1013 W which, although still pretty huge, could probably be
achieved with a thermonuclear device over a few seconds. I guess my
message here is that making big changes in the motion of something as
large as an asteroid using brute force methods are simply not possible
with technology we have .
QUESTION:
If the maximum velocity of
any particle or electromagnetic radiation is the speed of light and if
light and other forms of electromagnetic radiation cannot escape a black
hole, then how could Hawking radiation be possible?
ANSWER:
Hawking radiation has nothing to do with what the speed of the radiation
is. The radiation, the existence of which is still controversial, is due
to esoteric quantum effects which are too technical for this site.
QUESTION:
Is it possible for a material to act as a superconductor
at absolute zero. I understand that matter can become superconductive at
temperetures around absolute zero, but I am unable to find a definative
answer as to whether or not this happens at absolute zero.
ANSWER:
Well, acheiving absolute zero is not physically possible, so you need
not concern yourself with what happens there. However, you may approach
arbitrarily close, so it is meaningful to ask what happens in the limit
of very small temperature approaching zero. If the material is known to
be superconducting it has undergone what is called a phase change where
the resisitivity of the material suddenly drops to zero at some
temperature. Then the resisitivity would remain zero as temperature
approached zero. If the material did not undergo a phase change, it
would not be superconducting in the limit as temperature approaches
zero.
QUESTION:
How much one cubic inch of sugar cube weigh?
ANSWER:
I looked up the density of granulated sugar, from which
sugar cubes are made, and found 849 kg/m3. From this you can find, by
using standard conversion factors, that the mass of one cubic inch of
sugar is 13.9 g or a weight of 0.491 oz.
QUESTION:
If you took a
radio antenna and had the technology to generate a eletrical AC signal
across the antenna with a frequency of around 6*1014 Hz, would you see
visible light coming from the antenna, or would it just be a really fast
oscillation of energy between eletric and magnetic fields? If it would
produce visible light, would similar frequencies give IR and UV and so
forth?
ANSWER:
You would see nothing. There might be some EM
radiation in the visible region but the intensity would be too small to
"see". The problem is that the antenna must have a size comparable to
the wavelength corresponding to the frequency for it to have any
appreciable intensity. The wavelengths for visible light are hundreds of
nanometers and so you would need to have an antenna comparable to the
size of an atom. In fact, atoms do act like little antennae and that is
where we normally get visible light.
QUESTION:
If a fine liquid
filled capillary tube is place horizontally and both ends are immersed
in the same liquid as that filling it, is the pressure at the midpoint
of the tube larger than that at the ends?
ANSWER:
Although I do
not know a lot about capillaries, I do know Newton's first law. If the
pressure were greater in the center than the left end, the fluid in the
left half of the tube would have a net force to the left which it cannot
since it would be in equilibrium. What I do know about capillaries is
that they depend on the meniscus to drive the fluid through the tube and
there would be no meniscus under the conditions you state.
QUESTION:
I actually have an idea that isn't possible currently,
but I'd still like to suggest it to you, because I'm vey concerned about
the effect of the greenhouse effect on mankind. Seeing how things are
going with it right now, time for all life on earth may be running out
faster than we think, and we MUST do something more than just fighting
oil companies emissions... Now to the point - I't is finally time that
people in the physics community would take a chance at designing and
building at least a working model of an ozone particle regenerating
machine. For the sake of the earth and mankind, I think it's at least
worth a good try.
ANSWER:
The ozone problem and the greenhouse
effect are not the same thing. The greenhouse effect comes from too much
CO2 in the atmosphere which traps the energy which light brings from the
sun. The ozone problem is that ozone is needed as a shield against
incoming ultraviolet radiation from the sun but is depleted by
introduction of chemicals which interact with it (like
chlorofluorocarbons in older refridgerants). I believe that restrictions
on these chemicals is making noticable effects in solving the ozone
problem. Regarding your suggestion, building any machine which can have
any kind of effect on something as huge as our atmosphere would be an
undertaking which would cost our entire GDP and more!
QUESTION:
Why is a 45 degree angle the best angle to shoot a water baloon to get
it to go the fartherest distance?
ANSWER:
See my earlier answer
pertaining to projectile motion. Inasmuch as the range R of a projectile
may be shown to be R=v2sin(2A)/g where v is the speed at launch, A is
the angle of launch, and g is the acceleration due to gravity, you can
see that the range is proportional to the sine of twice the launch
angle. At 450 the sin(2x45)=sin(90)=1 which is the biggest the sine can
be.
QUESTION:
What exactly do scientists mean by "folding a
spectrum through a filter transmission profile" ? What is folding?
ANSWER: (Courtesy of J. Scott Shaw)
In astronomy it means
multiplying the intensity of the spectrum by the transmission % of the
filter at each wavelength to get the resulting intensity at the
detector. Or you can do it from the detector to the spectrum, depending
on how you need to see the problem.
ANSWER: (Courtesy of Richard S.
Meltzer)
I think this refers to the alteration of the actual spectrum
by the transmission of a filter so that what is observed is so modified
by the filter transmission. If one knows the transmission of the filter
as a function of frequency, one can deduce the actual spectrum from the
observed spectrum by dividing the observed spectrum by the transmission
of the filter.
QUESTION:
a light bulb uses 60J of energy to give
6J of useful heat energy. true or false???
ANSWER:
False. An
incandescent light bulb is only about 5% efficient, that is 95% of the
energy goes into heat. Your question is sort of strange because I
wouldn't call heat useful energy. We usually use a light bulb for light,
not heat, so it is the light which would be thought of as useful. If the
question had said "useful light energy" instead, it would not have been
far off.
QUESTION:
Can you tell me the wavelength of the EM wave
that would correspond to the photon emitted when a hydrogen atom's
electron falls from the n2 to the n1 energy level?
ANSWER:
121.566 nm. See
http://hyperphysics.phy-astr.gsu.edu/hbase/tables/hydspec.html
QUESTION:
I am learning about half-lives and am curious: is it
possible to shorten the half-life of radioactive decay?
ANSWER:
The short and practical answer to your question is no. The half life for
the transition from one state of a system to another is determined only
by the wave functions before and after (a wave function is a
mathematical construct which contains all the information about the
system). However, if you were able to change the wave functions by
changing the environment, you could change the half life; for example if
you put the radioactive nuclei in a very strong electric field you would
change the wave functions. However, the force which holds the nucleus
together is so strong, it would be virtually impossible to make a
noticable change in this way. What is more conveniently done is to
transmute the original nucleus: for example, if you add a neutron to a
radioactive nucleus you would likely form a new radioactive nucleus but
with a very different half life. This has been discussed as a way of
dealing with radioactive waste from reactors.
QUESTION:
Is there
any very important reason too why a coulomb is 6.24x10 exponent 18
electrons? i do not know very much about the coulomb
ANSWER:
The Coulomb (C) is defined in terms of the Ampere (A). The Ampere is an
electric current carrying 1 C/s. The Ampere is operationally defined in
terms of the magnetic force between two current carrying wires. So the
answer is that the fact that there are a certain number of electrons in
a Coulomb has no significance.
QUESTION:
In nuclear reactions,
when they are bombarding atoms with a neutron n for example, How do they
get just a neutron (fission) by itself to hit at a certain velocity?
ANSWER:
You are referring to nuclear fission reactions in a
reactor, I presume. Every time one of the fuel nuclei splits into two
pieces, it also releases several fast neutrons. These neutrons may then
be used to cause other nuclei to split and so forth. This is called a
self sustaining reaction--once you get it started, it will keep going as
long as one or more neutron, on average, causes another fission. The
problem is that fast neutrons have a very low probability of being
captured by a nucleus and are most likely to just fly away; if we slow
them down, however, they have a high probability of causing another
fission (simply because a slow neutron spends more time passing through
a nucleus than a fast one). So we must slow them down for the reactor to
work. The way that this is done is to introduce a moderator which is
efficient in slowing them down. Good moderators are water or graphite.
QUESTION:
Besides being released in beta decay and making up for
the excess of mass when a proton+electron are froce to bcome a neutron
what does the elementary particle "neutrino" actually do??
ANSWER:
What do you mean by "do"? The question is more appropriately "what are
the neutrino's properties?" To get a full discussion of neutrinos I
would recommend the Wikepedia article.
QUESTION:
What is the
formula for the range of a projectile?
ANSWER:
Neglecting air
friction and assuming that it lands at the same height at which it was
launched, R=v2sin(2A)/g where v is the speed at launch, A is the angle
of launch, and g is the acceleration due to gravity (9.8 m/s2). You can
find plenty of derivations of this formula on the web by googling
"projectile range".
QUESTION:
;
We say that centripital force is
centre-seeking and that it pulls the rotating object to the centre of
rotation. If this is the case then what force is responsible for pulling
the object outwards. For example, with a yo-yo rotating in a horizontal
plain. The tention in the string pulls the yo-yo inward, keeping it from
flying off. However, what is the force that causes the yo-yo to extend
outard? Is this the centripital force? If so then doesn't this mean that
centripital force pulls outward on the yo-yo while the force of tension
pulls inward on the yoyo?
ANSWER:
A ball going around in a
circle has an acceleration pointing toward the center of the circle.
Newton's second law thus says there must be a force pointing toward the
center of the circle and this is called the centripetal force. Any
number of forces with components in that direction may contribute to the
centripetal force, but the simple example you give has just the tension
in the string providing the centripetal force. There are no other forces
(in the horizontal plane) acting on the yoyo. Your statement referring
to the yoyo "extending out" makes no sense; if the string breaks the
yoyo does not fly radially outward but continues in the direction of its
motion at the instant the string breaks. If you imagine yourself to be
the string, there will be a force outward on you which is equal in
magnitude to the tension in the string. This is because of Newton's
third law: if one object (string) exerts a force on another object
(yoyo) then the other (yoyo) exerts an equal and opposite on the first
(string). But this outward force is not on the yoyo.
QUESTION:
According to Einstein's special theory of relativity ,velocity of light
is a universal constent .It does not change with respect to observers
velocity relative to the source of light .But I had heard that Doppler
effect occurs due to the relative velocity between the source and the
observer .Then if relativity theory is true,why doppler effect occurs?
ANSWER:
You have answered the question yourself. The postulate says
that the speed is constant, not that the frequency or wavelength are.
The frequency or wavelength of light does depend on the motion of the
observer.
QUESTION:
I am a teacher and I was wondering how I
can address students' misconception that weight does ot affect
accleration due to gravity. We did several controlled experiments to
determine the variables that affect the speed of a car rolling down a
ramp. In one experiment with a car and ramp, the weight was changed as
the car was timed from point A to point B. Some groups of students found
that sometimes the more weight added to the car, the faster it
acclerated down the ramp, while other groups found that the more weight
added, the slower the car rolled down a ramp. So now they are confused.
How can I steer them away from this misconception?
ANSWER:
The
design of the experiment must take into account all the variables. One
of the most troublesome variables in doing mechanics problems is
friction and I am sure that changes in friction as you change other
variables is what is causing trouble here. So, I propose the simplest of
all experiments to convince them that acceleration is independent of
mass if it is the only (nonnegligible) force present: just do Galileo's
experiment of dropping a marble and a bowling ball (or some similar
pair) simultaneously and see them hit simultaneously. This would be most
effective out of a second floor window, but you can drop them from six
feet in the classroom and have a pretty convincing experiment. Of
course, you could also use a feather and a bowling ball but the feather
would be the loser by far, not because of its (smaller) weight but
because of its (larger) frictional force. At a nearby college or
university you might be able to borrow an apparatus in which there is a
feather and a marble inside a glass tube which, if you pump the air out,
the two will fall with the same acceleration. If your students
understand Newton's second law you might find my previous discussion of
this problem helpful. Another experiment you could do if you have access
to an air table is to use it for your races and minimize friction.
I
helped my son with a pinewood derby a couple of years ago and I can tell
you that it is not easy to understand the physics of these little cars.
One thing which is often noted is that the fraction of the wheels
rubbing on the axels is quite important and using graphite as a
lubricant often speeds them up.
QUESTION:
How much evergy is
released, when a drop of water changes its shape from a cube to a sphere
of the same volume? How much is the drop getting warmer as a consequence
of it?
ANSWER:
The work done in changing the surface area by dA
is ydA where y is the surface tension which, for water-air interface
near 20o C is about 73x10-3 N/m. The surface area of the cube is about
24% larger than the sphere with equal volume (which I am assuming is
easy for you to show). So the energy released is about 0.24x73x10-3xA
where A is the area (4pr2) of the sphere. For a sphere of water with
radius 1 mm I estimate an energy of about 2.3x10-7 J. I will leave it to
you to compute the temperature change for this amount of water when this
amount of energy is added; you just need to calculate the mass m of the
drop and set the energy equal to mcDT where c is specific heat of water
and DT is the temperature change.
QUESTION:
I made this question
up myself when pondering how to teach Newton's 3rd law: A pulse of
electricity through a wire produces an electromagnetic field that
travels outward at the speed of light. This field encounters a charge
and exerts the appropriate forces on it. While the forces are occuring
on the charge, on what is the reactionary 3rd law force? I believe that
the closed loop nature of the fields would render the net work done as
zero.
ANSWER:
Here is a dirty little secret we never reveal to
our students in introductory physics: Newton's third law is not always
true! Particularly in electrodynamics, it is rather easy to see in
simple examples. The culprit, as you seem to have intuited, is the
magnetic forces. As a simple example suppose you have a particle (#1) of
charge q moving in the positive x-direction with speed v along the
positive x-axis and a particle (#2) of charge q moving in the positive y
direction with speed v along the positive y-axis. Particle 1 sees a
magnetic field pointing in the negative z-direction due to particle 2 so
it experiences a force in the positive y-direction; particle 2 sees a
magnetic field pointing in the positive z-direction due to particle 1 so
it experiences a force in the positive x-direction. Of course, each
particle also experiences a repulsive electrostatic force but these do
obey Newton's third law. But the net force does not. If the magnetic
forces involved were due to magnetostatic forces, long steady currents,
Newton's third law would be obeyed (as in the well known force between
two long parallel current carrying wires on which the definition of the
Ampere is based). It turns out that for the electromagnetic field, one
must include energy and momentum densities of the fields themselves to
do Newtonian mechanics and then all is well. If you want to pursue this
further, I would recommend the intermediate-level E&M book by Griffiths.
QUESTION:
My question regards a discrepancy between answers I get
when I work a problem using two different approaches. This problem was
given to me several years ago, and although I got the right answer then,
I was told that I could have also used a different approach. I have
tried several times since to do this problem the other way, but have had
no luck. The problem is this: if a pole of length L is stood on end and
released, if the initial velocity is neglegible, what is the final
velocity of a point at the end of the pole when it hits the ground. I
believe I originally solved this problem using the concept of the
potential energy being converted to kinetic energy (mgL=(1/2)mv2),
getting an answer of v=(2(g)(L))^(1/2). I am now trying to solve it
using calculus by integrating the equation v2=2ad over all da from 0 to
9.81m/s2 (where d is the arc length of the falling pole), and taking the
square root of both sides. When I do this I end up with an answer of
v=(( PI)(g)(L))^(1/2). What am I doing wrong?
ANSWER:
Neither of
your methods is correct. The second method, using v2=2ad is wrong
because this equation is valid only if the point has uniform
acceleration which it does not. The first method is incorrect because
you treat the stick as a point mass at the end of the stick falling
straight down which is not what is happening. The only way to solve this
problem in closed form is to use energy conservation as you have tried
to do; however, you must use rotational dynamics to do this. So the
potential energy at the beginning is mgL/2 because the center of mass of
the body is located halfway up the stick; the kinetic energy when the
stick hits the ground is Iw2/2 where I is the moment of inertia of a the
stick about its end (which is ML2/3 for a uniform stick of mass M and
length L) and w is the angular velocity of the stick (which is v/L if v
is the speed of the point at the end). If you now equate the energies
before and after and do the algebra, you will find v=(3gL)1/2.
QUESTION:
Do physicists believe that the world is continuous or
discrete? In other words, is there a smallest distance a particle can
travel and/or a smallest increment in time?
ANSWER:
This is an
open question. Although nobody has seen any evidence for the
discreteness of space or time, many serious theorists, particularly
those working in quantum gravity, believe that there does exist a
distance which is the smallest possible distance called the Planck
length. This length is on the order of 10-35 m so it is not surprising
that there is no experimental evidence for it since this is 10-20 times
the size of a proton! Similarly, time is thought to have the smallest
possible duration which is the time it would take light to travel the
Planck length, also very small.
QUESTION:
What guarantees that
human made particle colliders won't create black holes eventualy as they
reach higher and higher collision energys? I ask this because if i
understand it correctley, black holes aren't created only out of the
large mass of the stars that go supernova, but they are created by the
large density that the large mass of the star creates in it's center
when the atoms if its center collapse. What i mean is: The star that
went supernova was heavier than the black hole it creates, yet it is not
a black hole. So this means that black holes are created by their large
density and not their large mass. This is why i want to know wether
particle colliders could create a (dangerous) balck hole here on eart,
beacause they also, like supernovas make atoms collapse into great
densitys.
ANSWER:
The possibility of a black hole being created
is still speculative, but there is the real possibility that a tiny
black hole (say 300 proton masses) may be created. However, black holes
do radiate energy (called Hawking radiation) and such a black hole, if
it were to exist, would totally evaporate in an unimaginably short
amount of time, before it would have time to suck up any mass.
QUESTION:
If you were in a black room with no
doors/windows/external light sources and every part of your body was the
same shade of black as the room and you lit a match, would you see your
shadow? Would you see your own hand?
ANSWER:
I presume that by
"black" you mean something which is a perfect absorber of
electromagnetic radiation. In that case you would not be able to tell if
light is falling on it or not by using your eyes as you usually do, i.e.
by seeing the reflected light. On the other hand, the energy carried by
the light would have to go somewhere and it would show up in increased
temperature of whatever absorbed it. Now, all objects radiate
electromagnetic energy but, in your example, things look black not
because they are not emitting any electromagnetic waves but rather that
nearly all this radiation is outside what eyes can see (in the
infrared). But the catch is that a perfect absorber is also a perfect
radiator, so all the energy from the lighted match will be reradiated
but mainly in the infrared so you couldn't see it. If you had an
infrared detector you would be able to "see" the shadow, etc.
QUESTION:
I just moved to an area with snow and find that whenever
it is snowing in the night, there is always this orange-ish "ambient
light" that seems particularly bright, bright enough that one can see
fairly well to the point where one can drive slowly without headlights
in unlit areas. i am wondering what is the source of this light. i am
fairly sure that it is not moonlight (there is light even when the sky
is covered with clouds, and the intensity of the light does not seem to
change during with moonphase). It might be street lights reflecting off
the snow, since the color of the light is orange-ish, but then again you
can see this light even when you are dozens of miles away from big
cities, and the intensity of the light does not seem to change as you
travel further from big cities.
ANSWER:
I feel pretty sure that
what you are seeing is what astronomers call light polution. The
characteristic orange color you are seeing would indicate that the
source is sodium vapor lamps, often used for city street lights. The
light, particularly if it is not directed toward the ground and is
transmitted upward can scatter from snow, water vapor, dust, smoke, etc.
in the air so that you can see it quite readily even at surprisingly
large distances from the city of its source.
QUESTION:
All of
the physics examples for gravity and projectiles depict freefall or
horizontal/angular from fixed start locations, eg: a ball dropping over
a cliff or a cannon shooting a ball. And I understand the results.
However, I have been unable to find any answer regarding specific
vertical scenarios. For example, if we are standing in an elevator that
is not moving, and drop a ball, it freefalls at 9.8 m/s/s. So we can
easily calculate the time from when it is dropped to when it hits the
floor. But what would occur if the elevator were moving upwards at a
constant velocity (not accelerating) of 2.5 m/s (the average elevator
speed), and you dropped a ball. Would the time for both balls to hit the
floor be identical? If the ball in the upward moving elevator maintained
a constant vertical velocity of 2.5 m/s during its freefall lifetime in
addition to the applied force of gravity I would think that they
would... However, I would assume that the vertical velocity of 2.5 m/s
would not remain constant for the lifetime of the ball's fall, as
gravity is directly opposing that upward velocity. The ball's vertical
upward velocity should decrease as a curve due to the gravitational
force applied in the exact opposite direction. Similar to what would
occur with a projectile that is fired vertically, the upward velocity
decreases and it then falls back down accelerating due to gravity. Now
since the elevator's floor is still moving upward at 2.5 m/s, the ball
dropped in the moving elevator should hit the floor first.
ANSWER:
The motion of the ball is the same in any frame of reference which moves
with constant velocity relative to the stationary elevator. The dropped
ball in the moving elevator takes precisely the same time to reach the
floor as it did when the elevator was not moving. To help you understand
this, keep in mind that when the ball was released in the moving
elevator, it had a speed of 2.5 m/s upward as seen from the ground.
Basically, you are touching on what is called the principle of
relativity, namely the laws of physics are the same in all inertial
frames of reference; an inertial frame of reference is any frame which
moves with constant velocity with respect to a frame of reference (for
example your stationary elevator) in which the laws of physics are true.
If your elevator had been accelerating upward with an acceleration of
2.5 m/s/s it would have been a different story. In this case, the ball
would appear to fall with an acceleration of (9.8+2.5) m/s/s and hit the
floor sooner.
QUESTION:
I have a question regaurding light and
energy. It is known that it is impossible to accelerate a particle as
fast as the speed of light due to the fact that it would take an
infinite amount of energy. However, a photon's energy is difined as
E=hf, where h is the product of Planck's constand and f is the frequency
of the photon. So, why can light have a finite amount of energy whereas
an accelerating particle can not?
ANSWER:
The photon has no mass
and therefore it is exempt from this rule (as is any massless particle).
All massless particles necessarily travel with the speed of light and
they are not accelerated to get there, they are created already going
that speed.
QUESTION:
Okay, hypothetically speaking, if there
was a chain strong enough to not break under the ridiculous amount of
stress and the chain was attached to the moon and the earth (probably by
a mad scientist) what would happen? Would the moon slowly be drawn into
the earth? Would the earth wind itself up in the chain as it rotates
upon it's axis and how fast would it wind up? would the chain have to be
built on the moon and lowered to earth? How would the chain be affected
by earth's gravity when it first hit the atmosphere? If it was possible
what type of material would the chain be and how thick would it need to
be? Would it heat up as it cut through earth's atmoshpere?
ANSWER:
When you first start, there is no need for the chain to be strong
because the moon is held in its orbit by gravity and any additional
force (the tension in the chain) would disrupt that orbit. To see this,
imagine the earth and moon to be point masses and there is a weightless
chain between them;there is no tension in the chain. Now, let's get a
little more real: no chain is weightless and so there would be tension
in it just to support its weight but it would vary from point to point
and still exert no force on the earth or the moon which would continue
to orbit each other as if the chain were not there. Now, let the earth
become its normal size. Since the earth rotates once on its axis every
24 hours but the moon goes once around the earth every 28 days, the
chain would pull the moon down like a fishing reel. There is an
analogous thing which has been discussed, having an "elevator" into
space (not as far as the moon, but farther than where communication
satellites are). Here, both to support its own weight and the weight it
carries up, the cable would have to be very strong. It has been
suggested that perhaps the cable could be fabricated of carbon
nanotubes. You might be interested in the Wikepedia article on space
elevators.
QUESTION:
I know that the length of an organ pipe (as
well as the speed of sound in air) determines the frequency of sound
produced within it. Does the diameter of the pipe have any effect on the
sound produced?
ANSWER:
What the length determines is the
fundamental frequency, but no musical instrument contains just the
fundamental. each note played by each instrument also contains what are
called overtones, other frequencies, usually simple multiples of the
fundamental. The relative intensities of the many frequencies produced
is called the timbre and it is what allows you to tell the difference
between an A played on a violin or an organ or a trumpet etc.
Geometrical properties of organ pipes other than its length determine
its timbre; design of organ pipes has evolved from trial and error and,
as such, is more an art than a science.
QUESTION:
What exactly
is oscilating when we're talking about the wave nature of a particle?
What are the bounds in which between it oscilates?
ANSWER:
There
is not a physical wave which you can visualize. It happens that
something called the wave function, which is intimately related to the
probability of the particle being found at some place at some time,
satisfies a wave equation. This equation, however, is not the usual one
since its solutions are necessarily complex, that is they contain both
real and imaginary parts. An imaginary number, the square root of
negative one, cannot be physical but often is very useful mathematically
in describing the physical world. To extract what you actually observe
in nature from the mathematics requires having techniques which remove
the imaginary parts of quantities. So, the oscillating is of a complex
quantity and, as such, is not visualizable.
QUESTION:
Suppose
you are given two iron rods, and you are told that one is a magnet and
the other is not. Using ONLY those two rods, how would you determine
which was a magnet and which was not?
ANSWER:
If you, at some
distance away, align one bar (A) perpendicular to the other (B) and
pointed toward B's center and bring it closer it will experience a
strong force along its direction if it is the magnet; this is because it
will attract B and Newton's third law says that A will feel an equal and
opposite force. On the other hand, if A is not the magnet, it will find
itself in a magnetic field which is nearly uniform and perpendicular to
its length, so it will become magnetized in the direction of the field;
however, a magnet in a uniform field feels no force so it will
experience very little force. I am assuming that the magnetized bar is a
simple dipole, that is one end is north and the other south.
QUESTION:
what keeps electrons energetically orbiting a nucleus?
ANSWER:
What keeps a satellite orbiting the earth? What keeps the
moon going around the earth or the earth going around the sun? In all
cases, once you give an object the energy required for a particular
orbit, conservation of energy keeps it from changing. If the earth were
to suddenly stop moving and drop into the sun, it would have far less
energy; where did that energy go? To change the orbit you need to add or
subtract energy to/from the object. What is particularly interesting
about an electron in an atom is that an electric charge running around
in a circle radiates energy (that is what an antenna is) and so the
energy should radiate away and the electron fall into the nucleus.
However, it does not and this observation started the whole branch of
physics called quantum mechanics: one of the laws of nature is that
bound objects are allowed to exist only in specific (quantized) energy
states and therefore, if in such a state, a particle cannot radiate its
energy away except all at once by going to a lower energy state. There
is, however, a lowest state (called the ground state) and if the atom is
in that state, it must stay there.
QUESTION:
Is nanomolecular
technology able to create a dimond saw blade from the carbon in the air?
Are nanobots able to create things out of carbon? What would happen if
Carbon was broken down again? (that is, carbon is an element, but can
you destroy or break it down futher?) ANSWER:
The only way to make
diamond is under extremely high pressures, so one could not just coat a
saw blade with carbon in the air and expect it to be diamond.Nanobots
are still in a very experimental stage and so what they can or cannot do
is open to question and interpretation. Most nanobots which exist have
the purpose of detection of something, for example bacteria or
particular chemicals. I don't think there would be a reason why,
someday, a nanobot couldn't fabricate things out of carbon or anything
else.Normal carbon (12C) is composed of 6 protons, 6 neutrons, and 6
electrons. You could make anything you like out of those 18 particles.
Some examples: 6 hydrogen atoms and 6 free neutrons.3 helium atoms6
"heavy hydrogen" atomsHowever, this kind of rearrangement takes much
more energy than chemistry and is not easy to do. The reason is that the
force which holds a nucleus together is the strongest force in nature so
it is tough to break nuclei apart. You could do some "chemical" type
breaking apart with much less energy by ionizing the atom, for example
remove one electron and you have a singly ionized carbon ion. You might
find the Wikepedia article on nanobots interesting.
QUESTION:
When accelerating from a stop with your car door open, the door swings
shut. Now given that the force applied to the door is thru its pivot
point there should not be a net torque on the door, so it shouldn't
move. To idealize the situation I have imagined an axle with a
rectangular mass attached accelerated (normal to the axle) in deep space
to negate gravity and air resistance. I'm thinking the "door" would not
pivot in this case, so that the pivoting experienced in the original
case is due to air resistance, some kind of unbalance of applied forces,
or maybe even the fact that the car is not an inertial frame.
ANSWER:
Idealize the hinge to be frictionless. Then there is no
torque about the hinge. However, the hinge can exert a force on the door
(or else it would be left behind when the car accelerated). The
direction of this force is forward so that, according to Newton's second
law, the center of mass will accelerate forward, as you know to be the
case. Now, ask yourself if there are any torques about the center of
mass of the door. There is the forward force which the hinge exerts and
this exerts a torque which will cause an angular acceleration about the
center of mass. If you sketch that force, you will see that the torque
will tend to close the door. You were right to be suspicious of whether
the car and the door not being inertial frames might be a problem. You
may not apply Newton's laws in noninertial frames but there are special
exceptions, the most important being if you ask about what happens in a
frame attached to the center of mass; even though not inertial, Newton's
laws remain vaild in this frame. That is why, after asking what forces
there were on the door, I switched to the center-of-mass frame.
QUESTION:
I am teaching physics at a Kansas high school, and my
students and I were debating over a problem. The problem is as follows:
Two 20-N boxes are placed on both ends of an ideal rope. The rope is
then passed over two pulleys fixed on each of the two edges of a fixed
table, so that one 20-N box hangs on one pulley, and the other 20-N box
hangs on the other pulley (the rope being continuous over the two
pulleys). We have been debating over the value of the tension in the
rope, whether it's 20 N or 40 N. Half of the class agrees with me that
the tension is going to be 20 N, but I cannot convince the rest of the
class that the tension is not 40 N, but rather, 20 N. (Or is it me who's
wrong?)
ANSWER:
Breathe easy--you are right! The tension in this
rope is 20 N. The tension at a point in a rope is defined as the force
which it exerts on what it is attached to. So you need to focus on one
box or the other. You now say, what are all the forces on that box? One
is its own weight which we know to be 20 N vertically down. Another is
the force which the rope exerts on it; technically we know neither the
magnitude nor direction of this force, but it is called the tension in
the rope at the point of attachment. There are no other forces on the
box. Since it is in equlibrium, all (both) forces must add to zero, so
the tension is 20 N straight up. And, for a rope of negligible mass the
tension must be the same everywhere on the rope; otherwise if you
inserted a tiny mass in the rope and the tension were different on one
side than the other, the tiny mass would not be in equilibrium.
QUESTION:
I attached magnets (round, penny-size, strong) magnets to
each of the three blades of my small wind turbine and a two-inch
opposite magnet stick to the pole for more power to push the blades.
Then I placed the wind turbine into a wind tunnel to test if if it
generates more energy than without. It did generate less energy...please
explain why. Do I need a stronger magnet stick ?
ANSWER:
As each
magnet on the turbine approaches the stationary magnet it is attracted
but as it goes away from the stationary magnet it is still attracted, so
this force will cause the turbine to alternately speed up and slow down
so you will get no net work from the magnets. Technically, you should
have gotten the same energy output but your experiment probably
increased the friction of the turbine and so you lost energy there.
QUESTION:
if you are in a train traveling half the speed of light,
and another train on a separate, parallel track, was approaching you,
also at half the speed of light, would you see the passing train travel
past you at the speed of light?
ANSWER:
Classically, that is
what you would think. But the theory of special relativity shows that
velocity addition in classical physics is wrong but you can only easily
see that it is wrong at very high speeds and half the speed of light
certainly qualifies! The speed you would see the other train approaching
would be 80% the speed of light.
QUESTION:
When boiling
distilled water in a pot, bubbles rise from the bottom. What is within
those bubbles? Would it be oxygen? If so, is the oxygen extracted from
the water? What happens to the hydrogen excess?
ANSWER:
When a
liquid is heated enough it transforms into a gas (this is called a phase
transition). The bubbles you see in a boiling liquid are simply little
volumes of gas within the liquid, so in your question there is just
water vapor inside the bubbles.
QUESTION:
If you were to drop an
ice cube and a shot glass from 4 feet up, which would land and break
first? Why?
QUESTION:
My question to you involves the feather
and bowling ball freefall experiement in a vacuum. Now I understand that
by removing the factors of air resistance that you free up the feather
to fall much faster than it normally would. But the part I'm having
trouble with is that they do indeed fall, gravity is obviously still
involved and the ball still outweighs the feather many times over. In
fact the term "weight" is defined by the amount of force gravity exerts
on an object's mass. (not totally clueless, I just look like I am) So by
that term should not the ball fall much more quickly since gravity has
that much influence on it?
ANSWER:
Since these two questions are
so similar, I will answer them with one answer. Ignoring or removing air
friction results in all falling objects as having the same vertical
acceleration, 9.8 m/s/s; that is the speed of any freely falling object
increases by 9.8 m/s as each second ticks by. Hence, the ice cube and
the shot glass and the feather and the bowling ball will all hit
simultaneously. To understand the "why" you need to know two things:
Newton's second law states that the acceleration of an object is
proportional to the force it experiences and inversely proportional to
its mass; if we define a unit of force to be that which causes one
kilogram to have an acceleration of 1 m/s/s, then a=F/m if F is in
Newtons. An object's weight, the force which the earth exerts on it, is
proportional to its mass. So we can write that W=mg where, for now, g is
just some constant; if we measure the weight in Newtons and the mass in
kilograms, then we find (by simply measuring) that g=9.8 m/s/s.Putting
these two things together for the case where the force in Newton's
second law is the weight of an object, then a=W/m=mg/m=g. Note that m
cancels out; this is the key to understanding. Although the weight is
proportional to the mass, the inertia (resistance to acceleration) is
also proportional to the mass, so all objects have the same
acceleration.
QUESTION:
Water is attracted to each other right.
So when you cut through ice are breaking this attraction. I mean what
happens when you break something or cut something at the
atomic/molecular level.
ANSWER:
In a solid, each molecule is
bonded to its nearest neighbors. The nature of the bond is very
complicated, but is similar to the bonds which bind molecules together.
When you break a solid, you break all such bonds which were along
surfaces which appear.
QUESTION:
I am writing in the interest of
hopefully resolving a question which had arisen in my workplace. One
gentleman poses the hypothetical situation of a motionless tank sitting
on solid ice which he describes as "very slick and smooth - so much so
that if one were to toss a penny across the surface then it would glide
on endlessly." He posits that the tank is then started and attempts to
move forward. His position is that the tank will not be able to move as
the treads would simply spin on the ice. His detractor posits that the
treads are moved by the wheels inside the treads and that this would be
able to propel the tank forward. So, would this tank be able to move
forward or not? If so, what propertys of physics would make it be able
to move and, if not, why would this tank not be able to move forward?
The gentleman's scenario also posits that there is no friction between
the tank treads and the ice. Is it realistic, physically speaking, to
posit these two surfaces touching and no friction existing between them?
ANSWER:
How genteel you are! The gentleman who says that the tank
will not move forward if the ice is perfectly frictionless is correct.
It is the force of friction which accelerates the tank forward, not the
force which the wheels exert on the treads; if the wheels exert a force
on the treads, then Newton's third law says the treads exert an equal
and opposite force on the wheels so the two cancell each other out. No
it is not possible to have a perfectly frictionless surface; it is
possible to get a good enough approximation, however, to do an
experiment which should convince the second gentleman.
QUESTION:
I assume that the "big bang" theory is correct, but to accomodate the
concept of infinity, it must be that this process is repeated or
cyclical. After the universe expands for quite some time, gravitational
pull will eventaully slow down the speed of expansion until it stops,
and then gravity will create an accelerating contraction when all matter
returns to a single space and time, when another "big bang" takes place.
While the universe is contracting, history and time go backwards, and we
live our lives again in reverse, and all cosmological events are
repeated in reverse order. This theory provides for infinity, and also
for the concept of "eternal life", that would be a cyclical event, half
the time going backward, but repeated for all eternity. Eternal life in
this way may not be just a religious belief. I don't know the math
involed, but this may be the "unified theory" unsolved by Einstein.
ANSWER:
Your basic premise, that the universe is fated to collapse
back on itself is not necessarily true. If the universe has more than a
critical amount of mass, it will eventually fall back; if it has less
than that amount of total mass, it will keep going forever. Determining
which of these possibilities describes our physical universe has been
one of the main quests of astrophysics for many years. However, recently
observations have been made that the expansion of the universe is
actually accelerating, so it seems more likely that the universe will
not collapse as you posit.
QUESTION:
What happens to all the
light photons that enter your eyes?
ANSWER:
For the most part,
they vanish giving their energy to heat or chemical reactions which
initiate nerve impulses which your brain detects and interprets.
QUESTION:
Why do high voltage devices (power lines, transformers,
etc) hum? They have no moving parts to vibrate, so what causes the
humming?
ANSWER:
If there is sound, then obviously something
must be moving. The hum you hear is usually 60 cycles (since that is the
standard for AC) and results from electric currents interacting with
magnetic fields. Suppose you have a thick wire which carries a current;
then there will be a magnetic field everywhere around that wire,
including inside it. The current will interact with the field and will
experience a force which causes it to move and since the frequency of
the field is 50 Hz, so is the motion (in response the the force) of the
wire.
QUESTION:
if two people are moving past each other at a
constant speed in an infinite empty space, to either one the universe
would be static and the other person would be in motion
(relativisticly). if two people were at a constant unmoving distance
from each other, but one of them was rotating at a constant speed, to
either one the universe would be static and the other person would be in
motion, correct? so if they were far enough apart, wouldn't the rotating
person see their friend travelling faster than the speed of light
(tengentially)?
ANSWER:
The two situations are not equivalent.
Assuming that in your first scenario each was an inertial frame (one in
which Newton's first law is true), then both are inertial frames and
each can rightly claim that he is at rest. In the second scenario, if
one is an inertial frame then the other (revolving around it) is not, so
the rotating frame cannot claim to be at rest.
QUESTION:
I
recently heard that if you shoot a bullet straight out with one hand and
drop a bullet to the ground from the same height with the other hand
then both bullets will hit the ground at the same time. Is this true and
why. It would seem that the bullet being shot would have much more
energy behind it abd take longer to expend that energy and hit the
ground.
ANSWER:
This is what happens assuming that there is no
air friction (which is actually a pretty poor approximation for
something going as fast as a bullet). But, if there were no air, they
would hit simultaneously. The reason is that they both move identically
in the vertical direction, that is they both have the same acceleration
vertically whereas the one shot moves with constant speed horizontally.
So, imagine having a horizontal spotlight which cast a shadow of the
shot bullet on a screen, a way of looking separately at its vertically
motion. The shadow would move in exactly the same way as the dropped
bullet.
QUESTION:
If the earth were to see an extreme increase
in mass, would it colapse and form a black hole?
ANSWER:
That
depends on how big an increase of mass. If big enough it could collapse
because of the gravitational force.
QUESTION:
i am working on a
pendulum and i want to know how the shorter the lenght of string the
quicker a pendulum completes a period? Could you also tell me how the
lenght of the string affects the period of a pendulum?
ANSWER:
The pendulum is a standard problem which any elementary physics text
will explain in detail. If the amplitude is small (it does not swing
through too big an angle), the period is approximately proportional to
the square root of the length; for example, if you make the length 4
times longer, the period will be twice as long.
QUESTION:
If one
places a lightbulb inside of a mirrored chamber, such that all surfaces
other than the lightbulb itself are made of the best mirrors available,
then turns the lightbulb on, does the chamber get brighter and brighter?
What will happen eventually? During this process, if one open the
chamber, will he see a flash of light?
ANSWER:
The answer to
your question is that, even if the mirrors were extremely reflective,
say 99.9% of the light was reflected, and since light travels so
incredibly fast, a pulse of light is gone before almost any time has
elapsed. It might be helpful for you to read an answer to an earlier
question sort of like yours.
QUESTION:
My friend and I are
arguing over which science one should study first. I say chemistry
because it is a "central science" which helps one understand other
sciences, but he says physics does this. Any thoughts?
ANSWER:
Physics is more fundamental than chemistry; scientists generally say
that if you understand something in terms of the laws of physics, you
understand it from "first principles". So you are right, from a
philosophical perspective and physics should be studied first. Chemistry
may be thought of as applied atomic and molecular physics. But, most
educators would agree with your friend as can be seen in any high school
science curriculum; chemistry should be taken first. The argument for
this point of view is that physics requires much more mathematics to do
properly, that is, chemistry can be understood empirically without
knowing a lot of mathematical details. If you are good at math and have
had enough of it, then physics might be better to take first. Actually,
I took physics first in high school and fell in love with it!
QUESTION:
I was recently watching a programme about the Hubble
Space Telescope and the pictures it had captured. It mentioned that the
pictures it captured were of galaxies forming millions of years ago-If
this is so- Could it then be possible for man, should he a find a way to
manipulate space travel, be able to position himself at a certain area
of space, at a certain distance and witness the birth of the milkyway
itself? or indeed the birth of Earth?..........perhaps even the birth of
man?
ANSWER:
Suppose that something happened here on earth 500
years ago and you were located at a distance of 500 light years from the
earth with a very good telescope. Then you would be able to witness that
event right now. But, here is the rub. You cannot get there from here
before the light from the event reached there because it is physically
impossible to travel faster than the speed of light; in other words, you
could get there in just under 500 years and you would be able to witness
what happened here tomorrow.
QUESTION:
My family is astounded
with long thin projections of ice that form regularly and randomly on
top of ice cubes since I began placing the ice cube trays in the freezer
door. Even when the door is unopened from the time the trays are filled
until the time the ice is well hardened, the needle like spears that
usually slant in various directions at about a 45 degree angle, still
form. Some of these projections reach a length of about an inch. On some
cubes there are large fat lumps that raise up somewhat like a low
volcano. The trays are stacked one on top of the other and the cubes in
the bottom one does not, of course, have these curious growths. Can you
explain how this happens?I
ANSWER: (Thanks to Professor Craig
Wiegert)
I've also witnessed this phenomenon. (Unfortunately,
automatic ice makers seem to be largely immune to this curiosity, so
it's been several years.) The creation of these ice spikes has to do
with the fact that the ice cube freezes from the outside in. The top
surface starts to "crust over" first, with the ice growing outward from
the edges of the cube (in the same way that lakes freeze over in colder
climes). Meanwhile, the sides and bottom of the cube also start to
freeze. Because ice is less dense than water, the growing "skin" of ice
starts to crowd out the unfrozen water at the center of the cube. The
water has nowhere to go but up. If the top surface of the cube is mostly
frozen except for a thin spot in the middle, the water will be pushed
out of that opening to form a bump. When the conditions are right, the
"bump" will instead become an ice tube (freezing from the outside in,
remember) and the water will be able to rise even higher. The end result
is the ice spike. Better descriptions, with lots of nice photos, movies,
and some experimental results, are available at:
http://www.its.caltech.edu/~atomic/snowcrystals/icespikes/icespikes.htm
and
http://www.physics.utoronto.ca/~smorris/edl/icespikes/icespikes.html
The best example I ever saw was in my family's backyard birdbath when we
lived in Oregon. A cold front had swept through overnight, and the next
morning we found an ice spike at least 4 inches tall protruding from the
center of the basin. There's probably a picture tucked away somewhere in
a family photo album...
QUESTION:
In deriving the equation for
pressure of an ideal gas, is the force exerted by a gas molecule on the
wall given by change in momentum/time between coliisions or change in
momentum /collision time?
ANSWER:
You do not actually want the
force delivered by an individual molecule but the average force per
molecule averaged over many collisions. If you knew the time per
collision, you could add many collisions, divide by the number, and find
the average force per molecule. But, if you watch a single molecule and
find the time between collisions for that molecule, you will find the
same result without having to know the details of the collision itself.
You get momentum transfer per unit time which is force due to that
molecule.
QUESTION:
When matter and anti-matter come into
contact,is the destruction complete.Do no elementry particles remain??
Is it just "gone"?
ANSWER:
Many different things can happen. The
best known matter/antimatter annihilation is when an electron and a
positron, both at rest, annihilate. In order to conserve energy, two
photons come out (photons are essentially light, electromagnetic
radiation but with no mass). Since physicists think of photons as
elementary particles (even though massless), the answer to your question
is no. If one or both of the electrons have energy (are moving), it is
possible for new particles (with mass) to be created in the process. The
most important thing is that the energy (including mass energy, mc2)
must be identical before and after the "destruction".
QUESTION:
If you were to drop two equal boxes of equal dimensions built with the
same material and you filled one with ping pong balls and the other with
bricks. You than proceded to drop them both simaltaneously out of an
airplane at 2000 feet. Which one would hit the ground first and why?
ANSWER:
In an elementary physics course you are taught that all
objects have the same acceleration, so from that perspective the motion
of the two boxes would be identical and they would therefore hit the
ground simultaneously. However, in the real world there is air friction
which is normally neglected when you first learn about free fall.
However, air friction is not negligible particularly if speeds get very
large. So, as you stipulate, the geometries of the two objects are the
same, they will both have equal air friction for a given speed. However,
when the air friction force equals the weight of the object, it will
stop accelerating and fall at constant speed; therefore the lighter box
will stop accelerating sooner and therefore hit the ground later.
QUESTION:
Hi! Why doesnt an electron emit radiation as it goes
around the atom is it not really accelerating? Does the equal + and -
charges make the dipole invisible.
ANSWER:
This may be an
unsatisfying answer, but it doesn't because it doesn't! The problem is
that our laws of classical physics do not work at very small distances
(or at very large speeds). It turns out that an object must be described
in terms of its "wave function" which is, essentially, a statement of
the probability of finding it somewhere. When you do the calculations
using the branch of physics called quantum mechanics, the wave function
is zero unless the electron is in only certain states (including the
ground state), so the probability of finding it in a slightly less
energetic orbit (as it would tend toward if radiating energy away) is
zero; hence, no radiation. An alternative way to look at it is to say
that the electron should be thought of as a wave; it turns out that the
wavelength of the wave is exactly right to fit in the orbit so the wave
interferes constructively with itself (just like a vibrating guitar
string). However, for a different orbit, the wave each time around
"destroys" itself.
QUESTION:
My wife and I were in a car
accident last night and I want to know how many G's our bodies
withstood. I weigh 175 and she 140. We were hit from behind at a speed
of 65-70 mph while at a complete stop. I was driving a 4Runner and the
woman who hit us was driving a Dodge Caravan. I'm afraid I don't have
the exact weight of each vehicle.
ANSWER:
That question cannot
be answered. It depends on how long the collision lasted, whether the
cars stuck together, how fast each car was going after the collision,
etc. The information you have given me is mainly irrelevant to computing
your acceleration (g's). Here is how you could make a rough estimate:
suppose that after a quarter of a second you were going 20 miles per
hour having started from rest. Then your average acceleration would have
been (20 mi/hr)x(1 hr/3600 s)x(5208 ft/1 mi)x(1 g/32 ft/s2)/(0.25 s)=3.7
g.
QUESTION:
I’m a PhD student in philosophy interested (but not
working in) the philosophical foundations of relativity. I have a couple
of questions dealing with the speed of light and special relativity. The
main question is number 3, the other two are auxiliary. Your response
would be greatly appreciated. I will also greatly appreciate it if you
could let me know whether there is some bibliography available dealing
with this kind of issues.
Why is the relativistic length contraction
– as it appears in the Lorentz transformation – a function of the speed
of light?Conceptually, it is possible that the speed of light had a
different value than it actually has. How would that have affected
special relativity (in particular length contraction for fast-moving
bodies)? I recommend your looking into the Mr. Tompkins in Wonderland
books by George Gamow.Suppose we will discover a "form of light" (call
it light*, symbolized c*) whose speed is double the speed of light, and
it is also invariant. This would enable us to send signals at this speed
and to use these signals to synchronize clocks so that we may provide an
empirically meaningful definition of simultaneity. Do we need to revise
special relativity and base the Lorentz transformation for length on
this new value (c*), instead of c? Which of the following possible
responses should be the case and why: a) we can do that; b) is it
impossible to do that; c) we must do that. ANSWER:
The answer is
that the fact that light has the same speed in all frames of reference
leads to this result. It is simple algebra and, if you are seriously
interested, you should take the time to learn the basics of special
relativity.Special relativity would have the same form it does. If the
speed of light were 100 miles/hr, effects like time dilation and length
contraction would be everyday phenomena which we would not find puzzling
at all. I recommend your looking into the Mr. Tompkins in Wonderland
books by George Gamow.This seems extremely unlikely since light is just
a manifestation of electromagnetism and its speed is predicted by
Maxwell's equations. For a new kind of invariant speed to exist, there
would have to be another fundamental force in nature the theory of which
predicts radiation of that speed. Since there is no good quantum theory
of gravity, that is a remote possibility; gravity waves, however, have
never been directly observed although their existence has been inferred
from energy loss of binary systems. It is usually assumed that gravity
waves move with the speed of light, but that is unverified. Regarding
your simultaneity question, there is never any problem defining when two
events are simultaneous. The problem is that events simultaneous in one
frame of reference are not simultaneous in other frames; having some
other universal speed is not going to change that.
QUESTION:
Why
there is a weightlessness in an artificial satellite?
ANSWER:
See the answer to the following question.
QUESTION:
I always
wondered about this question and was hoping you can shed some light on
it for me. I noticed on Star Trek, they have gravity on their
spaceships. I know this is a sci-fi program and realize its all
fictional based on some scientific facts. But, I always wondered , why
can't we put gravity on the spacestation we have orbiting our planet
now? I know we have simulated 0 gravity on earth. Why can't gravity be
simulated on a spacestation in space?
ANSWER:
The only way we
know to "simulate gravity" is to be in an accelerating frame of
reference. If you are in a frame accelerating down with an acceleration
of 9.8 m/s2 near the earth (e.g. a freely falling elevator) you will
feel weightless. That is why you are weightless in the space station
because it is in free fall, just like the elevator but it is a free
falling projectile. To create "gravity" you would have to have a local
acceleration of 9.8 m/s2; the way to do this is to have a very large
donut shaped space station (say maybe a few hundred meters across) which
is rotating with the right speed so that you could walk around the
inside of the outer surface feeling as if there were gravity.
QUESTION:
Suppose a star is 2 light years from earth. A ship leaves
earth and travels to the star and then returns to earth. If the ship
travels at very close to the speed of light , it should take close to 2
years for the trip, as measured by someone on earth. But would the time
for the trip be close to 0 , as measured by someone on the ship?
Mathematically, if t is the time for the trip, as measured by someone on
the ship, and v is the velocity of the ship, does t tend to 0 as v tends
to c ?
ANSWER:
The answer to your questions are "yes" and "yes".
Of course, you made a small mistake in that it would about take 4 years
to make the round trip at close to the speed of light. You might be
interested in my previous discussion of the twin paradox.
QUESTION:
Why does light travel faster than sound? In Grade 11 physics, I am
learning that everything that goes through the same medium should travel
at the same speed.
ANSWER:
It is incorrect to say that
everything that goes through the same medium has the same speed. When I
walk through air, I don't go at the speed of sound. Maybe what the idea
is is that all waves traveling in a particular medium have the same
speed. The medium through which sound travels is air and all sound waves
go (approximately) the same speed. However, when light passes through
air, air is not the medium through which allows it to travel, that is if
we take away the air, the light will still go through but the sound will
not. Finally I should note that even the statement that all waves in a
medium have the same speed is incorrect. The speed which a wave moves
through a medium depends on its frequency; this is called dispersion and
is why a prism splits white light into a rainbow.
QUESTION:
According the Law of Conservation of Mass (or matter), matter is neither
created nor destroyed, it simply changes form. So, when a baby is
gestating, where do the atoms that make up that fetus come from? My
thought is that the matter is coming from two sources: the sperm and egg
to begin with, and from the food that the mother is ingesting to nourish
the fetus. (And I suppose the air she is breathing contributes to the
nourishment of the fetus.) Would that be correct? I figure that's where
new plants come from....they pull atoms of nourishment from the ground
and that helps build the plant itself.
ANSWER:
First of all,
there is no such thing as conservation of mass. Energy is what is
conserved and matter is a kind of energy (you know, E=mc2). The idea of
conservation of mass is a 19th century concept and comes from chemistry
where it is generally assumed that if you have a certain mass of
hydrogen and the appropriate mass of oxygen and if they combine to form
water, the mass of the water will equal the sum of the masses of
hydrogen and oxygen. However, if you could make an accurate enough
measurement, you would find that the water had a little less mass than
the hydrogen plus oxygen (because you must put energy in to break the
water apart and it shows up as mass in the end). That said, the forces
holding molecules together are incredibly weak and so the change of mass
in chemical reactions is incredibly small, so, for all intents and
purposes, mass is conserved. And therefore, you are right that the
mother supplies all the mass (after conception). And, yes, plants get
their mass for growth from the ground and the air.
QUESTION:
I
am investigating a factor that affects the period of a conical pendulum,
so after a little theoritical work* I decided to vary the lenght of the
cord while keeping other variables constant. My question is "does the
initial speed affect the period?" and What is the best way to design
this experiment using simple lab equipments?
* I came up with this
formula>
T = 2pi*sqrt(L*cos(a)/g)
T = period
sqrt = square
root of ()
L = lenght of the cord
a = angle between the cord and
the vertical
ANSWER:
Your equation is right. The initial speed
does not appear in the equation, but the motion certainly depends on it
because for the pendulum to be a conical pendulum with a particular
angle a, it is necessary that the speed be just right. Hence, v is
"hiding" in a. In fact, you should be able to show that v=sqrt[(Lg
sin2(a)/cos(a))]. Design your experiment so that you can vary L as well
as a so that you can measure T and compare experiment with theory. The
tricky part might be launching it with the right speed at each angle;
trial and error is probably ok.
QUESTION:
The Heisenberg
Uncertainty Principle states for a photon that: (certainty of
energy)*(certainty of lifetime)=k If a photon's speed is always = c,
then a photon can't age. My question is: if photons don't age, then how
can there be uncertainty about their lifetime?
ANSWER:
"Aging"
has nothing to do with anything here. Also, you should state the
uncertainty principle in terms of uncertainties, not certainties. In the
case of a photon, its energy is exactly hf where h is Planck's constant
and f is the frequency of the associated electromagnetic wave. Hence,
the uncertainty of the energy is zero, so to obey the uncertainty
principle, the uncertainty of the lifetime is infinite; as you know,
photons are stable particles.
QUESTION:
Electrons have two
possible states, spin up and spin down; no one electron is forbidden
from changing from one state to the other, yet how does an electron
create the energy from within to change states?
ANSWER:
For an
isolated electron, there is no energy difference between the two states.
QUESTION:
if i understand correctly light travels at a fixed
speed, and so it takes, for example, 8 minutes for sunlight to travel to
earth. if this is so, is everything is see in the past, allowing for the
light's travel time? and if so, is an object i see at 50 metres closer
in time than an object seen at 100 metres?
ANSWER:
This is
certainly right. In simple physical terms, when you make a physical
measurement you must make allowance for the time of transit of the
information to you.
QUESTION:
When I studied the force of
gravity in a college physics class, I always wondered how one object
could exert a force on another object or how one "knew" the other was
there. Later, in trying to understand Einstein's general theory of
relativity I came to understand that gravity is not due to objects
acting upon each other but rather from a distortion that occurs in the
geometry of space-time (like the bowling ball on the trampoline idea)
which results in the illusion of an attraction. More recently, I've been
reading about a particle called the graviton which physicists
hypothesize travels back and forth between massive objects at the speed
of light resulting in the "attraction". So, which one is it? The
distortion of space-time or the "messenger" particles zipping back and
forth? Or both? And if both, how do the two concepts fit together?
ANSWER:
The operative word here is "hypothesize". The idea of a
graviton is based on expectations that we should be able to understand
gravity from the perspective of quantum physics. However, there is no
remotely successful theory of quantum gravity and it remains one of
physics' "holy grails". The theory of general relativity is very
successful but not reconcilable with quantum mechanics.
QUESTION:
The discussion is if there was such a thing as a indoor wakeboard
training facility would the hydro dynamics be such that if water speed
was equal in the following scenarios could equal amounts of 'big air' be
obtained.
A 200# wake boarder is being towed behind a boat at a
distance of 60' at 20 mph. The wake height is 24" high and has a 45
degree angle on the outside of the wake. The wake boarder has sufficient
skill to cut in from outside the wake and obtain a height of 36" and
travel 20'. Rope mounting height is 36" above water level. The same 200#
wake boarder is in a wave pool capable of creating the same water
conditions as being towed behind a boat at a distance of 60' at 20 mph.
Same wake characteristics and same skill level from the same wake
boarder. Will the Wake boarder be able to obtain the same height and
distance as he would behind a boat? Same rope, rope height same
everything. Some of us say yes some say no. Some are of the opinion that
forward momentum generated by the boat would enable greater distances to
be obtained. Others say that the height and distance would be equal
because it is the speed of the water going by and the ability to
generate speed perpendicular to the direction of the water that provides
the speed to obtain height and distance.
ANSWER:
You are going
to have the water going by in #2 with the same speed as the boat in
#1--good. You are going to have a wake with the same characteristics
(same height and motion relative to the wakeboarder)--good, although I
am not convinced that it would be easy to actually do this since the
wake shape has to be essentially at rest relative to the wakeboarder
whereas the water per se is not. What you do not talk about is the air.
In #1 there is a significant wind in the face of the wakeboarder so you
better have a big fan for #2. I believe that air friction will play a
very important role after he lifts off, that is he will essentially fly
like a ski jumper. I think that if you don't forget the air, it will be
a pretty good simulation. Incidentally, the boat has nothing to do with
the mechanics of the wakeboarder because they are not in contact so the
boat cannot exert any forces on him. Whatever happens to the wakeboarder
depends only on his interactions with water, air, and rope (and, of
course gravity).
QUESTION:
around 1930, Dirac solved electron
spin and magnetic moment by treated the electron as a point particle. i
ask, is the electron a point? what is meant by a point particle?
ANSWER:
To the best of my knowledge, nobody has measured a
structure of an electron, that is it really appears to be a point
particle, something which occupies zero space. However, most scientists
I know are uncomfortable with infinities in nature and such a particle
would be infinitely small and have infinitely large density (because it
has nonzero mass). Another aspect of your question is that elementary
particles all, as you know, exhibit wave-like properties and as such the
meaning of "size" becomes sort of fuzzy.
QUESTION:
Regarding the
Stern-Gerlach experiment of 1922 concerning space quantization, does
this mean that electrons come in two flavors, spin up and spin down?
ANSWER:
Spin up and spin down have meaning only if up and down have
a meaning. Hence, you must first choose a coordinate system in which to
make measurements. When you do this, you may say that electrons have two
possible states, spin up and spin down. However, a particular electron
may be in a state which is a combination of some probability of each.
Quantum mechanics is weird!
QUESTION:
Given the length of a
column of air in a musical instrument changes the frequency of the note
(shorter column, higher pitch), I assumed that this was why adding water
to a wineglass changed its frequency when made to "sing". However, on
reflection, adding more water to a wineglass lowers the pitch. Given
adding more water decreased the length of the column of air, this can't
be the correct explanation (shorter column of are should increase the
frequency). Moreover, I've done the same "experiment" with the wineglass
submerged to the same depth as it was previously filled (ie., water is
at the same height on the outside, as it was previously on the inside).
The pitch was the same in both cases. I've also noted that the same
volume of water at a higher temperature increases the pitch of the note.
My question is what is the correct explanation for the change of pitch
of a "singing" wineglass? (I think that is must be something to do with
the damping effect of the water in direct contact with the glass. This
makes sense given at a higher temp, the density of the water is lower,
therefore the absorption of sound energy is less for the same height of
water in contact with the glass. Less absorption, less change in
frequency.)
ANSWER:
The reason is that it is not the air column
but rather the glass which is resonating. Think of a mass on a spring:
if you increase the mass (inertia) you decrease the frequency and I
think that is what you are doing by adding water, increasing inertia
against vibration. In that light, it is not surprising that you get the
same frequency whether the water is inside or outside the glass
(although I would not expect them to be precisely the same). The
temperature effect may simply be that you are changing the elasticity
(spring constant) of the glass by changing the temperature; try heating
the glass without adding water.
QUESTION:
Since the speed of
light is a finite number why would it take an infinite amount of energy
for a spacecraft to trave at the speed of light? *i understand that the
faster you go the more massive you become, but you cannot be infinitely
massive to reach a finite speed. It doesn't make sense to me. Maybe
Infinite mass and infinite energy should be replaced by "unknown"?
ANSWER:
You are thinking about this all wrong. What you have to do,
once you understand relativity, is to compute the total amount of work
which you must do in order to acquire a speed v for a particle whose
mass is m. In classical physics this turns out to be mv2/2, but
classical physics is only approximately true and becomes invalid for
high speeds. The correct expression for the kinetic energy, the work you
do, is mc2/(1-v2/c2)1/2-mc2. (Here m is the mass of the object at rest.)
This expression may be shown to reduce to mv2/2 for v much smaller than
c but clearly becomes infinite for v=c. Thus, to accelerate a particle
to the speed of light requires an infinite amount of work (energy).
QUESTION:
I am a 16 year old student currently enrolled in Physics
at my high school. I was given an extra credit assignment in which I
have to figure out all the steps to convert meters per second to miles
per hour. I need to know every single step in completing the conversion.
I have done research, and have found nothing that has helped me out.
Thank you for your time.
ANSWER:
The trick to unit conversion is
to repeatedly multiply by 1.0 (we can always do that, right?) until the
units are what we want. Since I will not do your homework for you (it
violates the groundrules of this site!), I will work out an analogous
problem. Suppose that I want to convert a pressure expressed in pounds
per square inch (psi) to the more "scientific" expression of newtons per
square meter. For a concrete example, let's do 14.7 psi which is about
atmospheric pressure:
14.7 (lb/in2)x(1 in/ 2.54 cm)2x(100 cm/1
m)2x(1 N/.225 lb)=1.01x105 N/m2.
QUESTION:
How much helium does
it take to fill a standard balloon ? Is there a way to measure helium ?
ANSWER:
First your second
QUESTION:
there is certainly a way to
measure helium, or anything for that matter. One way is to simply
measure its mass (in grams or kilograms). Another, often more useful
way, is to measure its molecular weight in moles where you have one mole
unit for each molecular weight unit. For example, atomic hydrogen has
molecular weight of 1 but it normally occurs as the H2 molecule, which
is two hydrogen atoms bound together so its molecular weight is 2.
Hence, one mole of H2 gas has a mass of 2 grams. Helium has a molecular
weight of 4, so one mole of hydrogen has a mass of 4 grams. The reason
that a mole is useful is that 1 mole of any material has the same number
of molecules, about 6 x 1023 which is called Avagadro's number. Of
course once you know Avagadro's number, you could also measure the
amount of helium by stating the total number of atoms in the sample.
Now, to your first
QUESTION:
I do not think there is such a thing as a
"standard" balloon, and it depends on how much you blow it up. Suppose
we have a balloon which has a volume of about one gallon which would be
about 4 liters which is V=4 x 10-3 m3. The pressure would have to be
bigger than atmospheric, so let's say that it is about 2 times
atmospheric pressure which would be about P=2 x 105 N/m2. Suppose that
the temperature is room temperature, about 200C which is, in absolute
temperature (kelvin) about T=2730K. Now there is a very useful equation
called the ideal gas law, which works extremely well for most gasses at
normal conditions which is PV=nRT where n is the number of moles of the
gas and R is called the universal gas constant and has a value of about
8.3 for the units of things I have used here. So, n=PV/RT=0.35 moles.
So, since a mole is 4 grams, the mass is about 1.4 grams. This answers
your question. By the way, 0.35 moles is about 2.1 x 1023 atoms.
QUESTION:
I was just wondering, could the principle of
superposition of waves be used to muffle or even silence a noise
projecting from a sound source? So, perhaps if a source of sound was
project a particular frequency, and i places another source of the same
frequency and ampilitude in another position, say half a wavelength
behind, could the original noise be silenced?
ANSWER:
Yes. In
fact, that is how noise-cancelling headphones work--the external sounds
are captured by a microphone, flipped, and added back to the incoming
sounds. Then you hear only (almost) the sounds being sent to the
headphones, music, talk, etc. Pilots often use this device so that the
hear only other crew members, ground controllers, etc. The answer to
your second question is also yes but you must also take care that the
two speakers are in phase. This kind of destructive interference is
responsible for "dead spots" in concert halls.
QUESTION:
Why is
heavy water (D2O) used in moderators of Nuclear Power Plants instead of
normal water (H2O)? If heavy water (D2O) absorbs and slows down the
neutrons emmited in fission what happens to it?
ANSWER:
The
purpose of a moderator is to slow neutrons down so that they will be
more probable to be absorbed by a fuel nucleus (e.g. uranium) and cause
a new fission. And each new fission becomes the source of more neutrons,
but they are fast and the moderator slows them down. If you use
something like lead as a moderator, it would work poorly because the
scattered neutrons would have almost no loss in speed (think of bb's
bouncing off bowling balls). But, if you use something light, like
hydrogen, then you are bouncing neutrons off something about the same
mass which will quickly slow them down (think of a head-on collision
between two billiard balls where the cue ball stops dead). So, hydrogen
gas or liquid would be the best moderator, but hydrogen is very
explosive, so we use something rich in hydrogen, water. But the problem
is that a single proton can easily combine with a slow neutron (to
create a deuteron) but that removes the neutron which we want to use to
cause more fissions. The purpose of the moderator is not to remove
neutrons, so we try the next lightest atom, deuterium, which is
chemically identical to hydrogen but has a mass about twice as big. It
is not quite such a good moderator, but it has a very small probability
of absorbing neutrons. In the event that it does absorb a neutron, it
becomes hydrogen with one proton and two neutrons and is called tritium.
Tritium is radioactive and harmful to the environment.
QUESTION:
I've heard of this experiment: Two parallel mirrors are set up and a
laser is fired perpendicularly between them. It is then possible to view
the beam of laser light (maybe with some dust or smoke between the
mirrors) falling towards the earth with an acceleration of -9.8 m/s/s.
Is this possible? If so, has this ever been performed?
ANSWER:
It is true that light will fall with an acceleration of 9.8 m/s2 (but
retaining a constant speed, that is the vertical component of the
velocity would increase), so in principle your device would work. But,
think about the scale of things. If the mirrors were 3 m apart, it would
take 10-8 s for the light to go from one to the other. In this time the
light would "fall" 9.8 x (10-8)2/2 m which is about 5 x 10-15 m, about
the size of a nucleus! I reckon (gt2/2) that it would take about a
hundredth of a second to fall 1 mm, right? But in this time, light
travels 3 x 108 x 10-2 = 3,000,000 m, a million reflections in our
device. But no real mirror is completely reflective; an amazingly good
mirror would be 99.9% reflective, but a million reflections would leave
you with about 10-435 (.9991,000,000) of the initial intensity! Clearly,
this seems to be an impossible experiment and I very much doubt that any
variation of it has been done.
QUESTION:
Would a type of
nuclear reaction take place if a proton entered a specific atom at a
certain rate, or if a neutron entered at a certain rate? Is this
considered the splitting of an atom or just one atom becomming another
atom? Would there be any kind of an explosion? What happens to the
gluons in each case?
ANSWER:
Just about anything which is
energetically possible can happen. Take some examples: a proton could be
absorbed by the nucleus and stay there creating the next element in the
periodic table; it could knock out a proton while passing through
creating the previous element in the periodic table; it could knock out
a neutron creating the next lightest isotope; the struck nucleus could
split into two heavy, but much lighter than the target, nuclei (called
fission); and just about anything you can think of, as long as there is
enough energy carried in by the proton to do it. "Splitting of an atom"
is a qualitative term but usually refers to fission. Neutrons are better
for causing nuclear reactions since slow neutrons can interact easily
with the nuclei whereas, since the proton and the nucleus both have
positive charge so it takes a much faster proton to get close enough to
the nucleus to interact with it (the nuclear force is very
short-ranged). Anything you can do which involves a single atom will not
cause what you would call an "explosion", but if you make many things
happen at once so that a large number of nuclei participate, you could
get something observable on a macroscopic scale. That is how an atomic
bomb works (or a reactor): one neutron causes a fission, but a fission
releases several other neutrons and some of those will create new
fissions, and so on and so on. There is no reason that a third grader
needs to be thinking about gluons!
QUESTION:
Assume two
identical objects A & B, with a rest mass of m, moving relative to each
other at a velocity V. The question is this: what is the energy
equivalent of A? According to relativity theory, the energy of A = mc2,
where I assume, m is the mass of the object from the point of view of an
observer in the same frame of reference as A. BUT, also according to
relativity theory, when an object moves, its mass increases, which we
will call M [capital M). So the the energy of A, since it is moving
relative to B, = Mc2. There then appears to be a paradox: the energy
equivalent of mass A is two different amounts, depending on whether the
observer is in the frame of reference of A (stationary) or B (who sees A
moving at velocity V). The object itself has no way of knowing whether
it is moving, so it seems there should be only one correct answer. Is
this a paradox?
ANSWER:
You do not have to do special relativity
to answer this question. Energy is a relative thing, its absolute value
has no meaning; all that matters is the amount by which it changes when
things happen. Take a book which sits on the table (and I am doing this
nonrelativistically). If I choose the position of the table top as the
level of zero gravitational potential energy, then this book has zero
energy. If I run past it, however, it moves relative to me with some
speed v and therefore has energy of mv2/2 (kinetic energy). If I raise
it some distance above the table top it now has some amount of potential
energy. It is always the same book but with just about any amount of
energy I like. No paradox. In relativity, mc2 (with m the mass of the
object at rest is called the restmass energy). If an object moves its
energy is Mc2 (with M the mass it has when moving). The kinetic energy
is by definition Mc2-mc2 and this will be approximately mv2/2 if v is
very small compared to c.
QUESTION:
V=IR
Either increase R
or I Voltage(V) will increase
Which of the two we are increasing in
a step up transformer while increasing the voltage as far as I know
Current (I) decreases while stepping up the voltage than is it the R
that we are increasing?
ANSWER:
A transformer is not an "Ohmic
device" and so Ohm's law is not true. The reason that I decreases when
the voltage increases is that energy must be conserved and the power,
the rate at which energy is consumed (or delivered) is P=IV. So
Pinput=Poutput.
QUESTION:
In Global Warming, I understand there
is a shifting of visible energy to longer wavelengths by the land mass
and oceans which then radiates this energy to the greenhouse gases in
the atmosphere which in turn re-radiates the energy back to earth. 1.
What accounts for the shifting of the energy from the shorter 400- 700
nm range) to the longer IR & ‘heat" wavelengths? Is it analogous to
Fluorescence spectral shifting phenomena? 2. In a theoretical situation,
if only pure visible wavelength energy fell on a perfect black body,
would the black body absorb all of this energy, raise its temperature
and reradiate it (at longer wavelengths) outward?
ANSWER:
Question number 1: Matter absorbs electromagnetic energy and the result
is that it heats up; a hot object radiates energy but mostly in the
infrared region.
Question number 2: Yes, except that the radiated
spectrum would depend on the final temperature of the black body. I.e.,
if the black body were originally very hot such that most of its energy
was at short wavelengths, the final spectrum would be hotter and peak at
even shorter wavelengths.
QUESTION:
How does a ballon gain
positive charge?
ANSWER:
What normally happens, since it is
negatively charged electrons which can be moved around most easily in
normal matter, is that an object becomes positively charged by losing
electrons.
QUESTION:
if you shot a bullet directly up, when it
came back down would its speed be the same as when it left the gun or
does terminal velocity prevent that.
ANSWER:
If there were no
air friction, the speed would be the same. But there is significant air
friction which takes kinetic energy away from the bullet, so it is going
more slowly when it hits the ground. Incidentally, because the earth is
rotating, the bullet would not hit precisely at the point from where it
was fired straight up.
QUESTION:
So we move with the earth
through space as it both orbits the sun and rotates on it's axis. Now
the closer we get to the speed of light the slower time passes for us.
Does this mean even when stationary on the ground our perception of the
passage of time is altered because the earth is moving fairly fast
through space? If so how much faster do we move through time then
someone not moving along with the earth or anything else. If not why?
ANSWER:
In your own frame, time will progress at a perfectly normal
rate. It is only the rate of your clocks relative to clocks in motion
with respect to you which run slower. See my discussion of the twin
paradox in an earlier question. Incidentally, the motion of the earth is
far too slow for any easily measurable effects to be observed since the
earth's speed relative to any other clock you are likely to compare it
to is very small compared to the speed of light.
QUESTION:
Does
the Heisenberg Uncertainty Principle say (a) that particles have a
definate position and momentum, but we are incapable of ever knowing
them both simultaneously or (b) that particles do not have a definate
position and momentum at all?
ANSWER:
Technically, one may know
one (position or momentum) with perfect precision if we are totally
ignorant of the other. However, we can never be totally ignorant of
either in practice (for example, surely the particle in question is
somewhere in the universe). So, both your (a) and your (b) are correct,
but (b) cannot be by itself a statement of the principle because the
degree to which we can know one is determined by the degree to which we
know the other.
QUESTION:
What is the shortest wavelength (I
assume in the gamma range) that has ever been experimentally observed.
ANSWER:
The most energetic photon which I could find reference to
was a cosmic ray of energy 3.2 x 1020 eV (observed in 2004 by the Fly's
Eye Detector). Since E=hf and f=c/l, l=ch/E=(3 x 108 m/s)(4.1 x 10-15 eV
s)/(3.2 x 1020 eV)=3.8 x 10-27 m. Here, h is Planck's constant and c is
the speed of light.
QUESTION:
Can you tell me if anyone has
studied the conection between gravity waves and bremmstralung? For
example if a charged mass were orbiting a significantly larger mass it
would emit both gravitational waves, (at least according to general
relativity) and electromagnetic waves. Has anyone studied at least the
theoretical model of this? How would the energy radiated by one field
compare to the other, both separately and simultaneously?Would they
radiate less energy when simultaneous?
ANSWER:
Electromagnetism
and General Relativity are separate theories. In the case you suggest,
both gravity waves and electromagnetic waves would be emitted and would
have nothing to do with each other as far as we know (although some have
suggested that general relativity may have effects on electromagnetism).
Both phenomena have been fully explored theoretically. I should of
course include a disclaimer here: nobody has ever directly observed a
gravity wave but some physicists are trying very hard.
QUESTION:
can matter at absolute zero be seen ? could dark matter be this ? i
mean, if matter was at absoulte zero, is it possible it still has mass
but we cannot see it ?
ANSWER:
Matter exactly at absolute zero
cannot be because of several laws of physics. However, let's suppose
that there were a chunk of matter at absolute zero. Could it be "seen",
that is detected? Well, if it were just sitting there by itself in
totally empty space we could not "see" it but then we could not see a
nearby piece of matter at any temperature. If light were to strike it, I
do not see why the light would not be either reflected or absorbed, and
in either case we could detect that so we could "see" it.
QUESTION:
Why does light travel in a srtaright line and sound don't?
ANSWER:
Light does not travel in a straight line necessarily any more than sound
does. The simplest example is a mirror which clearly changes the
direction of light. Light is also bent by entering a different medium
which is how lenses work. Light is also bent (ever so slightly) by
gravity. Light is also bend by diffraction (for example, you can never
make a perfectly sharp shadow of something because light bends as it
passes the edges.
QUESTION:
I have a problem with the standard
explanation of atmospheric pressure as beeing caused by the weight of
the air lying above. If i have a hermetic closed bowl of glass (or
something else), so there is no way forces can be transmitted from the
inside to the outside, how am I to explain the pressure in the bowl as
caused by the weight of the air above ?
ANSWER:
What matters is
the environment when you close the bowl. If you simply close it in
atmospheric pressure, there will be atmospheric pressure inside it. If
you were then to pump the atmosphere away, the pressure inside the bowl
would still be the same. If you were to pump more air into the bowl, the
pressure would increase and pumping it out would decrease the pressure.
These subsequent changes would be due to you, not the atmosphere.
QUESTION:
I'm not quite sure that I understand the theory of
relativity. Is it true that light NEVER slows down; that instead, time
is slowing down? (such that the m/s speed of light is the same as
always, but a second becomes longer)
ANSWER:
The speed of light
in a vacuum is always the same, regardless of the motion of the source
or the observer. As a consequence of this, moving clocks run slowly
(which is called "time dilation"). Light does move more slowly in a
medium (say glass, air, water,...) which is responsible for optical
instruments like eyeglasses, cameras, telescopes, etc. working.
QUESTION:
If the half life period for say Uranium is constant then
it should be that every atom of particular mass of Uranium degrade
simultaneously and say after the half life for one atom whole number of
atoms in that mass should get degraded and hence no more remians mass of
Uranium but some thing else. Is it so?
ANSWER:
What half life
means is that at that time half the number of original atoms will be
converted into something else. It is useful only for a very large number
of atoms because radioactive decay is a statistical process and you
cannot know when any given nucleus will decay, only what the probability
for decay is. After many half lives almost all the uranium will be gone.
QUESTION:
What generates more energy? A explosion or an implosion?
Also, which takes more energy to create?
ANSWER:
This question
has no meaning in physics. In the overall picture, energy is conserved
in any case. Take a conventional bomb (TNT): Energy is chemically
released from the explosive TNT and reappears as light, heat, sound, and
the kinetic energy of the fragments. The same is true for the case of
implosion: Chemistry provides energy but there are no fragments flying
out so more of the original energy ends up as heat, light, and sound
than in the case of the explosion. In all cases, something provides a
certain amount of energy and it shows up somewhere else.
QUESTION:
How does beta particle radiation produce heat energy? Does it do it by
merely striking a nucleus and increasing the movement of the atom? I
have never read material that explains that a beta particle strikes a
nucleus and increases the vibration or movement of the atom itself. Or
is the heat energy produced when the beta particle knocks an electron
off of an atom and then the atom later picks up another electron and so
produces heat in an indirect fashion (an exothermic reaction where the
atom picks up an electron)? To me that would be the conversion of
kinetic energy of the beta particle to heat energy.
ANSWER:
The
beta particle is just an electron (or positron) and loses its energy
almost entirely by interacting with the atomic electrons, not the
nuclei. Atoms become excited or ionize, then deexcite and emit
electromagnetic radiation (light, x-rays, etc.) which gets reabsorbed
and eventually ends up as heat, increased kinetic energy of the absorber
atoms.
QUESTION:
Using the electron flow model is it correct to
assume that flow is from the earth to the generator?Is it correct to
assume that the earth is negative in regards to the generator?Or is the
generator more negative than ground?
ANSWER:
One of the most
important points about electric potential is that its zero is arbitrary.
We usually call the point where we define zero potential to be "ground"
or "earth", but that point need not be the actual physical earth. The
one thing which you may be certain of is that electrons will always flow
from low potential to high potential. Thus, if you call the earth zero
potential and if your generator is at +5 volts, then electrons will flow
to the generator. On the other hand, if the generator happens to be at
-5 volts, electrons will flow from the generator.
QUESTION:
I am
fascinated by magnetism, most likely because I do not understand its
limits. I recently read somewhere that it has been determined that
gravity "flows" at the speed of light (i.e. if the sun were to
inexplicably vanish, it would still take eight minutes for it to
disappear from the sky and for the earth to drift from it's orbit). Does
a magnetic field behave similarly, or is it instantaneous in effect?
ANSWER:
Electromagnetic fields all propogate at the speed of light.
Thus, if you created a magnet on the sun, it would take 8 minutes before
you saw the magnetic field on the earth.
QUESTION:
What is
equivalent of 250 rpm in x gravity?
ANSWER:
I presume that you
want to know how many g's of acceleration 250 rpm is. Well, you have not
given me enough information because the acceleration depends on the
radius of the circle the object is moving in. The acceleration of an
object with speed v moving in a circle of radius R is v2/R. So the
acceleration of an moving at 250 rpm which is 250/60 rps=4.17 s-1. So,
the speed would be v=2pR x 4.17=26.2R m/s. So, the acceleration would be
a=(26.2R)2/R=685R with the answer being in m/s2 if R is expressed in m.
The acceleration due to gravity is 9.8 m/s2, so a=685R/9.8=69.9R in g's.
So, for example if R=0.5 m, a=35 g's.
QUESTION:
If e=mc2 than
what does happen when --e=-mc2. Will time stand still? If you go
backward and time is always trying to catch up would you not be caught
in in a loop.
ANSWER:
Sorry, this question doesn't really make
any sense. You might want to study some about Dirac who postulated a
filled "negative energy sea". When a particle is elevated from this sea
to the realm of positive energy it leaves a hole behind. This hole is an
antiparticle.
Note to this questioner: I cannot answer your questions
about a career in physics because the email address you gave me does not
work. Also questions of this sort I will often answer but not here
because this site should be reserved for physics questions.
QUESTION:
During the past several months, I have been working my
way thru an "Elementary Modern Physics" by Weidner & Sells (circa 1962).
For the most part, I been able to handle the majority of the problems,
but have slammed into several that I can't breakdown. One of these is as
follows: "What is the mimimum speed of a particle such that its kinetic
energy can be written as its total energy E, and therefore as pc, with
an error in total energy no greater than 1%?" This implies that this is
in the extreme region where E~pc (momentum) & this confirmed by the
solution below. I have not been able to set-up the equation required to
yeild the solution = 0.9995c. What seemed routine at first has become
something else. At least one author said to ignore the rest mass energy
in the extreme region, but when I do that I get E=pc or mc^2 = mvc ,
hence v=c & this not correct. There has to be some small factor (~1 in
2,000) to achieve the text's solution. However, when I write E = Eo + KE
& try to work it thru I get "bogged down" in the algerba with
(1-beta^2)^0.5 factor. I'm about out of bullets & to the point of
frustration. It's clear to me that I have missed something in my
understanding of the set-up of the initial equation. I am asking for any
coaching & direction you or perhaps a graduate student might have. I'm
also working thru a similar one that has a different twist ......."it
asks what's the maximum speed a particle can move so that its KE can be
written as 1/2 Mo*v^2?" If I can solve the one above then I think this
one will fall out.
ANSWER:
A detailed answer may be read here.
FOLLOWUP QUESTIONS:
You indicated that m always refers to rest mass
(Mo), and I assume that the momentum (p) in these equations refers to
the classical momentum p=Mo*v, otherwise the terms would not cancel out?
I did not see any use of the gamma term. Am I correct?also, since you
knew that this was "slow speed relative to c "........... is this the
reason to use classical in this application? ANSWERS:
No, p is
relativistic momentum, mu/sqrt(1-u2/c2) where u is particle speed.The
gamma is in p. I view linear momentum as the thing that is redefined in
relativistic mechanics, not mass. It must be redefined to have momentum
conserved in an isolated system.What I know is that in the limit of
small u special relativity must reduce to Newtonian mechanics. Hence, we
must have T=.5mv2 for u<<c or equivalently pc<<mc2.The email address you
used to send your question does not accept my email to you!
QUESTION:
If there was a circular race track, and it had three
lanes; one car on the inside lane and one car on the outside lane. Would
the centrifugal (or is it centripetal) force of the cars be equal if it
takes the same time for them to complete a lap. Because while the one on
the outside lane is traveling faster; it has a softer angle. The one in
the inside lane is travelling slower but with a sharper angle. I thought
of this when tryingt o go to sleep in the car and feeling the
centrifugal force when going round bends.
ANSWER:
First let's
get straight the difference between centripetal and centrifugal forces:
an object moving with speed v in a circle of radius R will have an
acceleration (called centripetal acceleration) v2/R. Because of Newton's
second law, a force must cause this acceleration, so F=mv2/R. If you are
riding in a car and leaning on the outer door, the door pushes on you
with with this force, called the centripetal force. Because of this real
push, you have the perception of being pushed against the door with a
force equal to the centripetal force; you are not really being pushed
into the door, you just feel that way. In physics this is what we call a
"fictitious force" and, in this case it is called the centrifugal force.
Another example is when the car is accelerating you feel that you are
being pushed back into your seat but what is really happening is that
the seat is pushing forward on you.
Now to your
QUESTION:
Since the
speed v=2pR/T if the period is T, the centrifugal and centripetal forces
(mv2/R) will not be the same for both cars because v2 is proportional to
R2. The ratio of the forces would be Fout/Fin=Rout/Rin, that is the
outer track would have larger force.
QUESTION:
What are colours,
does it have any physical mass?
ANSWER:
Color is a qualitative
way to describe the differences between wavelengths of visible light as
perceived by our eyes and brain. It is not an object, so to ask if it
has mass is meaningless. Photons, from which light is composed, have
energy but no mass.
QUESTION:
if there is an object with zero
inertia, and there are enormous forces of the same strength pulling at
it from all directions, so the all cancel out. will it take some effort
to move this object? or will the object be like.. nothing?
ANSWER:
Dynamically, an object with zero net force on it (as you describe) is
identical to one with no forces on it, so we need only ask ourselves
what happens when we exert a force on an object with zero mass. It will
experience infinite acceleration because a=F/m; by the same token, an
object with zero mass can have an acceleration when there is no net
force on it. This all sounds quite bizarre, but keep in mind that there
is nothing with zero mass (photons do not count because classical
mechanics does not apply to them.) We often talk about objects with zero
mass in elementary physics problems, for example "...the pulley is
massless and frictionless" but these should be understood as
approximations, that is the mass of the pulley is very small compared to
other masses in the problem. A force acting on an object with very small
force will result in a very large acceleration.
QUESTION:
Do
photons have mass? In one of your answers you say no. My penquin
dictionary of science says, no mass. However, in the September 2006
issue of ASTRONOMY, the article, ASK ASTRO page 63. It is stated that
the photon's mass is less than 10(-50)kilograms. Or 14 orders of
magnitude smaller than a neutrino. Very low mass, yes, but there is
mass. Is a photon massless?
ANSWER:
When we say that photons
have no mass, we mean that every measurement we have ever made is
consistent with their having no mass. However, it is often of interest
to test the limits of our knowledge: how accurately do we know that the
photon is massless? Most likely the article you were reading put an
upper limit on what the mass of a photon could be based on experiments,
10-50 kg.
QUESTION:
I was wondering whether or not one could
accelerate a mass of about 1 kilogram in a large particle accelerator to
nearly the speed of light. If this is possible, how fast would the mass
go, how large would the particle acclerator have to be, and how much
energy would be needed to acclerate the mass? Also, what type of energy
is released when two particles or in this case one kilogram objects
collide or what percent would be light and what percent would be heat.
ANSWER:
It is not feasible to accelerate a 1 kg mass in a particle
accelerator because the 1 kg mass is not charged. Even if you caused it
to become highly charged, the force of gravity on it (its own weight)
would be larger than any electrostatic force you could exert on it so
the accelerator would not work. The speed, if close to the speed of
light as you stipulate, would be about 3x108 m/s. The energy would be
about 1026 times larger than the energy of a proton having the same
speed. The energy of 1 kg going 99% the speed of light would be about
6.4x1020 Joules. If you accelerated it to this energy over the time of
one year, you would have to continuously supply over the year about
20,000 Gigawatts of power! There is no way to know exactly what will
happen when two objects collide.
QUESTION:
Do electrons contain
photons? Electrons emit photons when elevated to higher energy level.
E=mc2. Photons are massless but are energy. Does not all energy have
mass? What happens to photons in a beam of light in a dark room when the
beam is switched off?
ANSWER:
We do not think of electrons as
"containing" photons although they are thought to be surrounded by a
cloud of virtual photons popping into and out of existence. The emission
of photons from excited atoms is due to a creation of a photon, not the
"release" of one. Not all energy has mass, the photon being the perfect
example. Every object has a total energy part of which is due to its
mass and part of which is due to its motion (kinetic energy). Photons
get absorbed by the walls in a dark room.
In future, please note that
one of the groundrules for this site is to ask single, well-focused
questions.
QUESTION:
Could the comparison of an atom and a solar
system exist with the current understanding of nano science. I.e. do
electrons orbit the nucleus of an atom in relation with a nuclei's
weight or mass? Do the nucleus' of atoms emit light?
ANSWER:
No.
Gravity is not the force which holds the electrons in their orbit. It is
the electrostatic force (the attraction between the negatively charged
electrons and positively charged nucleus) which does it. Gravitational
forces in an atom are entirely negligible compared to the electrostatic
force. Mass, however, is not irrelevant, however. The mass of an
electron is very small compared to the mass of the nucleus, so the
nucleus, for all intents and purposes, remains fixed as the electrons
orbit. If the mass of an electron and a proton in a hydrogen atom were
equal, the two would orbit about a point halfway between them, much like
a binary star.
Regarding your second question, yes a nucleus emits
"light" but not light you could see. When an atom emits light it is
often within the visible spectrum. The electromagnetic (called gamma
rays) waves emitted from nuclei are much more energetic and thus of a
far shorter wavelength than your eye can see.
QUESTION:
I'm a
photographer. I take photos that take advantage of what I call
'gravitational lensing'. I set up a black rod between the camera and the
subject. If I get just the right 'focus' setting on the camera I can get
the the background and the rods out of focus but the areas of overlap
seem to come into focus. My guess is that, when the photons travel from
the background to the camera they are pulled closer together by the mass
of the rod and therefor they appear in more focus. The best examples are
images #0518a and #0512 at
http://www.morgan-anderson.com/artwork/2005Works.html I've been working
with this phenomenon for a couple years and, while I have a cursory
understanding of it, I'd like to know for certain what I'm doing. So My
question is: what is the physics behind this?
ANSWER:
Let's
first dispense with what the explanation cannot be. Since the
gravitational pull on light is so incredibly weak, there is no
possibility that the mass of the rod can have any observable effect on
light; deflection of light passing close to the sun, with huge mass, is
extremely small and difficult to observe. For this reason, you should
probably not call, even whimsically, what you are seeing "gravitational
lensing" because, whatever it is, it certainly has nothing to do with
gravity. What it most looks like is diffraction. When you put an
obstacle in the way of light, the light which comes from either side of
the object interferes and results in light and dark fringes. What
worries me about this explanation, however, is that diffraction is
usually hard to see except for monochromatic light and what you see
seems to come from the whole spectrum. So maybe there is some
explanation from geometrical optics (optics which does not depend on the
wave nature of light), but I would need more information to make any
further guess: how thick are the rods, is there more than one of them,
where are they relative to the camera, where is the focus of the camera
when you see these effects? Being a photographer, you should probably
take it upon yourself to learn about diffraction.
QUESTION:
I
teach Science in Oconee County, Georgia. In class one day we were
discussing the Northern Lights and they are "cosmic radiation" that is
being burned up in our atmosphere at the poles due to the high
concentration of magetism from the earth's magnetic field. I had two
questions, wondering if you guys might be able to help me answer the
questions:
I wanted to make sure I was correct in the cause for the
northern and southern lights. I had a student ask, why we couldn't use
large magnets or even the magnetic north/south pole to stop large scale
radiation type attacks, ie. whether it be a nuclear war, an atomic bomb,
or even to help clean up something like the leak at the Russian nuclear
plant? ANSWER:
Referring to northern lights as "radiation...being
burned up" is inaccurate. Here is a brief explanation: There is a
constant stream of electrons and protons which come from the sun called
the "solar wind". (During times of intense sunspot activity the
intensity of these particles increases.) If the earth did not have a
magnetic field, these particles would simply plow through the earth's
atmosphere (ionizing and exciting atoms as they went) and then hit the
ground where they would lose all their energy. But, because the earth is
like a giant bar magnet, these incoming charged particles get deflected
and their tendency, because of the nature of the magnetic force, is to
spiral around the magnetic field lines toward the poles. Hence, there is
a concentration of these charged particles around the poles (which is
why the aurora phenomena are usually very far north or south) and as
they follow the field lines down, they strike the upper atmosphere. When
these energetic particles hit the air, they ionize (knock off an
electron or two) the atoms along the way and when these ions recombine
with electrons, light is emmitted--hence the "lights" part of the
phenomenon. So, you see, it is not really a case of radiation being
"cleaned up" at all. The cases you refer to are nuclear radiation and
there the most damaging radiation is usually gamma radiation which is
very energetic electromagnetic radiation (like x-rays but even more
energetic); since gamma rays have no electric charge, they are totally
unaffected by magnetic fields.
QUESTION:
Does the refractive
index of salt solution change with its concerntration? If yes, what is
the best way to determine it?
ANSWER:
I can't imagine that it
would not vary. There are numerous ways to measure index of refraction,
too many to enumerate here. Generally, you need to have a setup which
allows you to measure the angle of refraction for a known incident angle
and use Snell's law. Another way to do it is to measure the critical
angle of total internal reflection.
QUESTION:
I know that we see
the colors of the visible spectrum from the interaction of the different
frequencies of visible light as seen from our eye and our brain. In
other words, there is no intrinsic "color" property for a specific
frequency of light. My question is this. If our eyes were sensitive to
say the ultraviolet region of the EM spectrum instead of the visible
region and the things around in our environment (i.e. trees, concrete,
buildings) reflected and absorbed the uv light like they do visible
light, would our eyes discern different "colors" for different
frequencies within the uv region? In other words, is there anything
special about the visible section of the spectrum or is it simply that
our eyes were made to see this region?
ANSWER:
The idea of color
is, as I see it, a purely subjective thing. In fact, how do I even know
that what you see as green is the same as I see as green? The only
thing, from a physics perspective, which matters is that you and I are
able to distinguish between different wavelengths of the spectrum to
which our eyes are sensitive (assuming that neither of us is color
blind). Also, it is necessary from a scientific point of view, that our
observations be repeatable, that is green, once I have learned it, will
never look red to me. Animals have a variety of color sensitivity which
you can learn about on the web by googling "color vision in animals".
Insects, which have an entirely different eye structure from other
animals, use primarily ultraviolet light since the resolution of their
eye is maximized for very short wavelengths. There is no simple answer
to your question since it depends on the detailed structure of your eye
(rods, cones, etc.), but there is no reason why, had our eyes evolved
like the insects to see ultraviolet light, we could not, in principle,
distinguish between different wavelengths of ultraviolet light.
QUESTION:
Usually when I get bored, I spin my chair. First I take a
spin with my legs in. When I strech my legs out, the speed decreases,
which is abvious because of the laws of the centrifugal force. The weird
think, though, is when I retract my legs again, the speed INcreases
after it has decreased. I asked my scince teacher about this conundrum,
and her suggestion was that perhaps I retracted my feet fast enough to
give my spin energy enough to spin faster. To me that just doesn't seem
right.
ANSWER:
First of all, there is no such thing as "the laws
of the centrifugal force", so though it may be obvious to you that you
slow down, it should not be! What you are experiencing here is
conservation of angular momentum. Angular momentum is the product of the
angular velocity (for example, the number of revolutions per second) and
the moment of inertia the object has relative to the axis about which it
is rotating. Moment of inertia is essentially a measure of how far away,
on average, the mass of the object is from the axis of rotation. So,
when your legs are in your moment of inertia is smaller than when your
legs are out. The angular momentum of an object remains constant (is
conserved) if there are no external torques on the system. You and the
chair spinning can be approximated as having no torque, although there
is some due to friction which will eventually, as you know, cause your
angular momentum to vanish (because you stop spinning). But, over the
short term, your angular momentum stays about the same, so if you put
your legs out your angular velocity must decrease and if you pull them
in, it must increase. This is the same principle dancers and skaters use
to increase their spin rate by pulling in their arms.
QUESTION:
Classical physics texts all have common problems where a horizontal
force acts on a triangular wedge with a rectangular block (of smaller
mass) sitting on the wedge's incline (the net force accelerates both
masses). Some problems have the surface between wedge & block as
frictionless & some don't. However, in all the problems I've seen, the
surface between the wedge & horizontal surface supporting it are
frictionless. Is this done to avoid the so called 3 body problem, or is
there another reason? Just curious.
ANSWER:
I am a stickler on
the way you state problems like this, so first let me reprimand (!) you
for a conceptual problem: The force pushes on the block and not the
wedge and therefore the force does not accelerate the wedge, the block
(which is touching it) does. The only thing you must make sure of is
that there are not more unknowns than equations. If you add friction to
the table surface, you have not added an unknown since it is
proportional to the normal force between the wedge and the table. So, if
you can do the frictionless problem you can do the one with friction. It
has nothing to do with the 3-body problem in which you cannot write an
analytical solution to the motion of three bodies mutually interacting
via central forces (like a planet with two moons).
QUESTION:
I
am trying to find the launch angle required for a ball to clear the net
of a tennis game. For example if I want to perform a drop shot no matter
where I stand in the court, I want to place the ball so that it lands
close to the net at the opposite side while making sure that it clears
the net. I manage to work out the formula for calculating the initial
start velocity required for the ball to reach the destination but I
can't quite figure out the formula required to clear the net. There is
one in-efficient solution I came up with, that is that I can just check
if it manage to clear the net, and if the ball failed to clear the net I
can increase the launch angle... but there got to be a better solution
for this.
ANSWER:
You seem to have too many unknowns as far as I
can figure out what you want to do. Here is what you can do: you can
choose a particular distance from the net, an initial velocity, and an
unknown launch angle, and an initial height from the ground. Then,
stipulating that the ball just clears the net, you should be able to
solve for the angle. You will get two answers: one corresponds to a
fairly low trajectory and one corresponds to a lob. The lob will hit
closer to the net.
QUESTION:
In my readings about relativity,
much is made of the equivalence of gravity from a mass, and acceleration
due to thrust, such as a space ship either sitting at sea level on a
planet vs. the same space ship accelerating at the equivalent rate in
free space. In fact, these two situations are supposed to be
indistinguishable by experimenter or experimenters within the space
ship. However, wouldn't they be able to discern which by using two
plumb-bobs, which in the case of being under thrust would be parallel to
each other but at rest on a body of matter, would each point towards the
center of mass of the body, and therefore make an angle (vanishingly
small under realistic conditions, but this is a thought experiment,
after all) to each other?
ANSWER:
You are right, you could
distinguish between an accelerating frame and a nonuniform gravitational
field, for example from a planet. The adea you allude to assumes the
gravitational field to which you compare the accelerating frame is
uniform.
QUESTION:
Many references define gyroscopic precession
as "a phenomenon occurring in rotating bodies in which an applied force
is manifested 90 degrees later in the direction of rotation from where
the force was applied." This does not jibe with my understanding, which
is that gyroscopic precession is the movement of a rotating body in a
gravitational field, where the axel on the axis of rotation is secured
at one end, and such axel sweeps out a cone. If my understanding is
correct, what do we call the phenomenon described above? My old college
physics text describes the phenomenon, and obviously mathematically
models it (with vector cross-products), but does not name the
phenomenon.
ANSWER:
Remember that Newton's second law for
translational motion may be expressed as force equals the time rate of
change of linear momentum. In rotational physics, the corresponding
statement is torque equals time rate of change of angular momentum.
Imagine a top spinning about an axis through its center of mass and in
empty space. Its angular momentum is along this axis and, since there
are no torques on the top, the spin axis stays fixed (no precession).
For example, the angular momentum of the earth points along the axis and
from south to north poles; the fact that this direction always points to
the north star demonstrates that the angular momentum is constant
(conserved). Now take the top and exert a torque on it (a spinning top,
unless standing straight up, has a torque due to its own weight). The
result, due to Newton's second law is that the angular momentum vector
will not remain constant; the way it changes is to change its direction,
hence precession. This is a simplified explanation; the top problem is
one of the classic problems in classical mechanics to understand in all
its gory detail. I hope this gives you a better qualitative
understanding.
QUESTION:
If two rockets of the same weight were
placed at the same height, and one was dropped in free fall and the
other launched horizontally, wouldn't the one dropped hit the ground
before the one flying would? (assume wind resistence is negligible)
ANSWER:
Yes, because I presume you mean by "launched" that its
rocket is burning; in principle, it could keep going horizontally until
it ran out of fuel. You are, I think, confusing this with the situation
where it is projected horizontally but does not have a rocket engine. In
this case, both hit the ground simultaneously.
QUESTION:
Is the
statement correct: "Today the temperature is 40 degrees Celsius and
yesterday it was 20 degrees Celsius so it is twice as hot today as it
was yesterday"
ANSWER:
Although "as hot" is a qualitative
statement, physicists would say certainly not. It is the Kelvin
temperature which determines the energy content of something, and the
Kelvin temperature is 273 degrees below the Celcius temperature. Thus
the two temperatures would be 313oK and 293oK. Maybe you could say that
40oK is twice as hot as 20oK
QUESTION:
What is the angular
momentum of the spin axis of an atomic nucleus? I have only heard about
this in advanced physics. Is there any way one could reverse the spin
axis of the angular momentum of an atom?
ANSWER:
The angular
momentum of a nucleus is the sum of the angular momenta of its
components. Each proton and each neutron has a spin (always 1/2 in
appropriate units) and an angular momentum due to its orbital motion
(always some integer in appropriate units); for each particle, its total
angular momentum is the sum of these (always a half odd integer, i.e.
1/2, 3/2, 5/2...) If the nucleus has an even number of protons and of
neutrons, the ground state angular momentum is always zero because it is
energetically favorable for pairs to sum up to zero angular momentum.
Only nuclei with odd numbers of particles or with an odd number of
protons and neutrons have ground state angular momenta. The total
angular momentum of a nucleus is usually referred to as its spin. To
"reverse" the spin, you just need to flip the direction of the spin
vector. So you should think of taking a spinning object and pointing its
spin axis in the opposite direction, not stopping and reversing it; the
effect is the same.
QUESTION:
Does everything in the universe
rotate in the same direction?
ANSWER:
No. However, most things
in the solar system do; if viewed from the north star, most objects in
the solar system rotate counterclockwise.
QUESTION:
Lets say you
had two rocket ships docked at a space station. They decided to leave
the space station at the exact same time in completely opposite
directions at 99% the speed of light. Both rockets traveled for one year
(relative to the rockets time) and then at the exact same time reversed
their directions and went back to the space station. The space station
has now "aged"... thousands of years from when they left. Have the two
rockets aged at the same rate? Would they each only be two years older
compared to each other then when they left? Would the same apply if they
traveled next to each or perpendicular to each others direction? How
does special relativity (I think that is what it's called) effect these
ships since you cannot say that one ship is moving 198% the speed of
light compared to another ship which may be concided stationary.
ANSWER:
I have earlier answered just about the same question.
QUESTION:
"energy is matter, and matter is energy" Is this
statement true?
ANSWER:
Matter is, indeed, a form of energy.
This is the famous E=mc2 relation of special relativity. I do not think
most physicists would say that energy is a form of matter, however. That
would sort of be like saying "horses are animals and animals are
horses"!
QUESTION:
Determine the distance to which the painter
of weight "w" can climb without causing the ladder to slip at its lower
end. The top of the 15kg ladder has a small roller and at the bottom of
the ladder the coefficinet of static friction is 0.25. The ladder is
1.5m away from the bottom of the side wall. I have drawn the free body
diagram and realise that we need to be in equilibrium, my problem is the
last step, How do I use this information to find the weight of the
painter and how far from the wall it is?
ANSWER:
Although you do
not specify it, I presume that you know the length of the ladder. Your
solution should have three equations: one from setting the sum of the
torques to zero and two from setting the sum of the forces (x and y
components) to zero. Thus you may find three unknowns. You do not know
the weight, the position of the painter, the normal forces of the wall
and floor on the ladder; the frictional force by the floor, may be
espressed in terms of the others since f=mNfloor. Seems to me that you
have 4 unknowns and therefore cannot solve the problem.
QUESTION:
can thermal expansion be stopped
ANSWER:
Of course, you just
have to push on the ends. This is analogous to containing a gas in a tin
can and heat it up; it wants to expand but cannot because the volume is
constrained so the pressure increases instead.
QUESTION:
I know
that when I look at a flourescent bulb through a diffraction grating, I
see emission lines, but why, when I look at a hot wire filament type
bulb through a diffraction grating, do I not see the absorbtion lines of
our own atmosphere between the wire and the grating? Why do I see a
complete spectrum?
ANSWER:
Absorbtion is a relatively low
probablilty event and there is not enough air between you and the light
bulb to cause enough absorbtion to be seen.
QUESTION:
I was
looking recently at old photos of the Space Shuttle in orbit. In one
particular photo, an astronaut is outside the shuttle--untethered and
over 300 feet from solid footing. He is, of course, equiped with his jet
pack (an EMU or something like that), but my question is this: how, once
the astronaut has exited the shuttle, does he remain at the same speed
as the shuttle is going? Let me clarify.... The shuttle is going 17,000
mph or so in orbit, as anyone sitting inside is also...what makes a
person who leaves the shuttle while it is in orbit stay in orbit along
with the shuttle, despite having drifted 300 feet or so away from the
departure point? The caption along with the picture described the
astronaut as a "literal human satalite." Why doesn't the shuttle speed
away from the man once he leaves?
ANSWER:
The only thing which
determines the speed is the orbit in which the satellite moves. When the
astronaut originally leaves the shuttle, he has the same orbit and moves
with the same speed. But if he does something which moves him 300 feet
away (for example, 300 feet farther away from the surface of the earth)
he will now have a different orbit and a different speed. However, his
percentage change in orbit radius is so incredibly small that the speed
difference will be incredibly small also. In principle, if you wait a
long time the two will get farther and farther apart.
QUESTION:
this is technically a "homework" question, but i disagree with the
answer given in the textbook--hopefully you can tell me why their answer
is valid. (or not) "an electron travelling at 0.25c and of rest mass
9.11*10-31 kg collides head on with a positron with the same mass but
travelling at 0.5c. when matter and antimatter meet in this way they
anihilate eachother to produce energy, how much energy is released" the
answers to the textbook just use E=mc2, with the rest masses of the
particles eg: E=2*9.11*10-31*(3*108)2 E=1.64*10-12 J However it seems
illogical to me that the velocity of the particles (significant
fractions of the speed of light) doesent influece the energy output. My
initial reaction is that the relativistic mass (Mv) should be used
instead.
ANSWER:
I would tend to agree with you that you should
include the kinetic energy of the two particles in the total energy
released. Thus,
E=9.11x10-31x[(1-.252)-1/2+(1-.52)-1/2]x(3x108)2=1.79x10-13 J. Then, for
example, if the annihilation resulted in two photons (the most common),
their energy would sum to 1.79x10-13 J, not 1.64x10-13 J as the book has
it (there must be an error of a factor of 10 in your answer above).
QUESTION:
im a senior citizen who completed a short senior course
on physics so maybe this is stupid.
l. is a photon also an electron?
2. does an electron ever break down into another particle and are
all electrons charged?
ANSWER:
1. No. A photon is light, it has
no mass and no electric charge; an electron has both.
2. No, an
electron is a stable particle. It is possible to collide electrons with
other particles and create new particles which do not include any
electrons.
QUESTION:
Is it true (as people say) that if you are
out-of-doors and trying to talk to a large group of people (e.g. a class
of students) that you should stand upwind of your listeners so that the
wind will carry the sound toward them rather than away? In other words,
in a moderately windy environment, does the direction of the wind have
an effect on how the sound travels through air?
1. I understand the
Dopler effect, but that refers to a moving sound source. My question is
a about a stationary source and receiver.
2. For the sake of this
question, let's *not* factor in that the apparent sound of the wind
changes when a person turns toward or away from the wind source. That
may have more to do with the shape of the listeners ears. I am
interested in the behavior of sound waves.
ANSWER:
The doppler
effect refers to either a moving source or a moving observer (the
fomulas are different, but the qualitative effects are the same). A wind
is equivalent to a moving observer. If you stand upwind of the receiver,
the sound will be doppler shifted to a lower frequency; downward to a
higher frequency. But the intensity will be unchanged. If you think of
your sound as being directed at a particular observer (like, for example
a flashlight beam if it were light), then you could get in trouble if
you had a crosswind which would result in the sound aimed at the
observer missing him.
QUESTION:
Is is possible for something, a
particle perhaps, to have mass but no volume? Matter is defined as
anything that has mass and volume. But, is there anything that exists as
a mass without volume? Much Mahalo for your help,
ANSWER:
Yes,
such a thing is called a "point mass" or a "singularity". Black holes
are thought to be singularities as are electrons.
QUESTION:
I
may be wrong, but it seems to me that a freezer full of cold food is
colder than the same freezer att he same temperature but filled with
air. Is one actually a few degrees colder than the other?
ANSWER:
"Colder" and "at the same temperature" are contradictory. Colder means
at a lower temperature.
QUESTION:
Would it be possible to
engineer an antenna which could radiate extremely short pulses of only 1
period ? (e.g. for a 1GHz frequency, the pulse would last only 1
nanosecond ) Would it be possible to radiate a period and a half ? (e.g.
for a 1 GHz frequency, the pulse would last 1.5 nanoseconds )
ANSWER:
It is possible but the engineering is not really the antenna
but the electronics to generate the pulse. However, is you take exactly
one period of 1 GHz sine wave, what you are left with is something which
does not have a single well-defined frequency but is rather made up of
all frequencies with 1 GHz being the maximum of the distribution. This
is a classic example application of Fourier analysis of waves. This kind
of "chopping" is routinely done with ultrashort laser pulses.
QUESTION:
Gravity and free fall. This is driving me crazy. Is the
moon really in free-fall? How does this relate to the notion that the
moon's "desire" to go straight is acted on by the earth's gravity and
results in an ellipse? And astronauts – are they really in free fall, or
just some metaphorical free-fall? Why don't the moon and astronauts
just..you know..fall? I keep reading websites on this, but I am still
confused.
ANSWER:
Is a stone which you throw horizonatlly in free
fall (neglecting air friction)? It is because anything which is moving
only under the influence of gravity is said to be in free fall. Imagine
your throwing the stone faster and faster; it will go farther and
farther until finally it goes all the way around the world and hits you
in the back! This is a satellite. (This is not my idea, but rather was
devised by Newton to understand the motion of satellites. Try it
yourself at
http://galileo.phys.virginia.edu/classes/109N/more_stuff/Applets/newt/newtmtn.html
QUESTION:
Imagine a man pushing a 10 kg cart horizontally across a
frictionless plane, accelerating it from 0 m/s to 20 m/s in 10 s. What
are the forces acting on the cart? I understand that there's F, the
man's push, and W, the cart's weight. What should F be? Is it just
simply: A) F = ma = (10 kg)(20 m/s - 0 m/s)/10 s = 20 N or B) F = ma + W
= (10 kg)(20 m/s - 0 m/s)/10 s + (10 kg)(9.8 m/s/s)= 20 N + 98 N = 118
N? Shouldn't W be simply neglected because it is perpendicular to the
direction of the object? Is the resistance the man feels when he pushes
simply the inertial mass, or inertial mass plus weight? (I know you
cannot add mass and force but well...) If W isn't neglected, shouldn't
the object dig diagonally into the surface, by the usual addition of
vectors?
ANSWER:
Your answer (A) is the right one. Your
reasoning is correct that this force is not in the direction of the
acceleration. What you have not noted is that the plane exerts an upward
force on the cart which is (for this problem) equal to the weight so
that the net force in the vertical direction is zero as it must be since
there is no acceleration in the vertical direction. Weight is a force
(which the earth exerts on a mass) and mass is mass, so it is the
inertial mass which is the m in F=ma.
QUESTION:
I was just
wondering why when you rub two items together (like your hand on carpet
for example) heat is generated? Where does that energy come from?
ANSWER:
It comes from you. When you cause the two surfaces to move
against each other you do work (a force acting over a distance) and work
adds energy to a system, in this case heat energy.
QUESTION:
A
recent experiment which involved converting energy into matter was
accomplished at S.L.A.C. (short for Stanford Linear Accelerator Center).
But while converting matter into energy is an easy feat, converting
energy into matter is not so simple. Furthermore, whenever matter is
being converted into energy, some of it is inevitably lost due to the
second law of thermodynamics. However, you could compensate by
disintegrating some rocks and adding in that energy too.
In Star
Trek, the way the transporter works is by separating crew members at the
atomic level and converting them into energy. Once they arrive at the
appointed destination, the process is reverse. Granted, Star Trek is
just a tv show, but let's say for the sake of argument that the
transporter operates by converting people into energy and vice-versa.
1) In order to convert a person into energy, wouldn't that mean
burning up that individual?
2) Would the person survive the
procedure, or would the individual ceased to exist and be replaced with
a replica, who was literally born into existence once the energy was
reconverted back into matter with the information? (Note: I know this
question sounds a bit philosophical but I'd be very interested in your
opinion anyway.)
ANSWER:
Several comments on your question.
The second law does not allow energy conservation to be violated.It is
not really hard to convert energy into mass. If you take a CO2 molecule
and pull it apart (adding energy by doing work) it gets heavier;
however, the amount of mass you make is too small to measure because
chemistry is a crummy way to get or store energy. However, if you take
the nucleus of an atom, say iron, and pull apart all the protons and
neutrons in it, it will get measurably heavier.What is tough is to
convert energy purely into mass. An example of where this does happen is
when a photon spontaneously creates an electron positron pair. This may
be made to happen provided the photon has sufficient energy and it
passes through a strong electric field (e.g. near some nucleus).In your
star trek question, "burning up" is not turning the person into pure
energy, rather it is like the inverse of the CO2 example above. Carbon
in the person combines with oxygen in the air to make CO2 thereby
releasing some energy, but all the carbon and oxygen atoms are still
there.Your question #2 is too far out to be physics, particularly since
there is no such thing as "beam me up Scotty".
QUESTION:
Hi. I've
heard that particles (light, for instance) can be sped up to speeds much
higher than the normally travel at. Could a similar process be used to
accelerate the movement of radio waves?
ANSWER:
Particles may be
accelerated to any velocity slower than the speed of light c (assuming
that you have the energy to do it) but electromagnetic waves (including
both light and radio waves) travel through empty space move with a speed
of c, no faster, no slower.
QUESTION:
WHY COULDN'T INERTIA OR
MOMENTUM BE CONSIDERED AS AN ETHER WAKE? IF AN OBJECT GAINS MASS AS IT
ACCERATES WHAT IS THIS MASS, WHERE DOES IT COME FROM IF NOT SOME CONCEPT
OF ETHER?
ANSWER:
I have no idea why you invoke the ether to
explain mass increase, particularly since it is generally acknowledged
that there is no such thing. Here is the orignin of "mass increase". If
one defines linear momentum as (rest) mass time velocity like we do in
classical physics, we find that the total linear momentum of an isolated
system is not conserved. this is a very bad situation from the
perspective of mechanics since the notion of a force is useless and the
valuable ideas of energy have no validity. However, if we redifine the
linear momentum as the quantity [1-(v2/c2)]-1/2 times mass times
velocity, both the linear momentum of an isolated system and its energy
are conserved. So, you need not ever say that mass increases, it is just
that momentum must be redefined to be useful. Many people choose to say
that m is redefined and momentum isn't (still mass times velocity but a
new kind of mass), but that is a point of view, not some kind of law.
QUESTION:
A recently published book on baseball pitching claims
that an arm/hand assembly travelling at 31 mph will allow for a ball to
be released at 95 mph. The author's contention is that, because of the
law of conservation of momentum, the larger mass of the arm travelling
at 31 mph will transfer momentum to the smaller mass of the ball, thus
causing it to accelerate to 95 mph in order to satisfy that law. It is
my contention that there can be no transfer of momentum unless there is
a sudden decrease in velocity of the carrier due to an external force
being applied, thus allowing the carrier to "give up" it's momentum to
the unconstrained object (the ball). I proposed this question. What
event has occurred from a point 1 millionth of a second prior to ball
release and a second point 1 millionth of a second after release that
causes momentum to be transferred? The masses of the arm and ball have
not changed. Therefore, the only variable in the momentum equation to
change is velocity. If the velocity is reduced by internal means,
muscular relaxation, the momentum will be not be transferred to the ball
but dissipated within the body. There is no external force, like a brick
wall to stop the arm, therefore there can be no transfer of momentum to
the ball. Am I correct here? Any help would be greatly appreciated.
ANSWER:
I feel quite certain that the speed of the part of the
"arm/hand assembly" (as you call it) which is in contact with the ball
is moving with the same speed as the ball when it is released. It is
totally fallacious to talk about the speed of the "arm/hand assembly"
because each part is moving with a different speed:
the shoulder has
a small speed due to motion forward of the bodythe elbow has a speed
which is the vector sum of the velocity of the shoulder and the velocity
of the elbow due to its rotation about the shoulderthe wrist has a speed
which is the vector sum of the velocity of the elbow and the velocity of
the wrist due to its rotation about the elbowthe hand (and ball) has a
speed which is the vector sum of the velocity of the wrist and the
velocity of the hand due to its rotation about the wristSo, you see, it
is not so simple.
QUESTION:
Studies over the years seem to
indicate that lightspeed is slowing down. If so, is it because photon
emmisions are somehow calibrated with the quanta about stable matter and
is a result of those particles being in a state of deceleration?
ANSWER:
I think that this is quite speculative and not at all
verified experimentally. Since the speed of light is what physicists
call a "fundamental constant", the question is an important one in
physics and philosophy since by definition, a constant cannot change. At
this point, trying to understand why a constant of nature might change
is perhaps premature.
QUESTION:
Why is the speed of light given
by 1/sqrt(permittivity *permeabillity)? What is the great mistery behind
such a simple relation? How these two parameters combine to give the
speed of light? Why does the vacuum (nothing...) has physical properties
such as permittivity and permeability?
ANSWER:
This is the great
triumph of Maxwell's work in the 19th century. There are laws of
electromagnetism which can be summarized in four equations, now known
collectively as Maxwell's equations. The quantity e0 (permittivity of
free space) is just a proportionality constant which tells you how
strong the electric force is and, of course, it appears in the
equations. Similarly, the quantity m0 (permeability of free space) is
just a proportionality constant which tells you how strong the magnetic
force is and, of course, it appears in the equations. (In this context,
there is nothing wrong with empty space having permittivity and
permeability because one certainly does not need matter between charges
or currents for them to exert forces on each other.) When Maxwell messed
around with the equations he discovered that they could be rewritten as
wave equations and that the speed of these waves had to be 1/[e0m0]1/2.
That this happened to be the speed of light was the point in the history
of physics that we understood what was doing the waving in light
waves--electric and magnetic fields.
QUESTION:
I've always
understood comets or meteors crash into the ground at a very high speed.
Is the meteor in the atmosphere for such a short amount of time, that it
can't be slowed to terminal velocity
ANSWER:
I believe that would
have to be the reason. Or else, it may be that the terminal velocity
would not be particularly slow.
QUESTION:
If someone built a
very tall vacuum chamber and dropped a bowling ball in it, assuming the
ball is dropped a great distance from the ground, how fast could the
ball fall? Would the Earth have a maximum pull on the ball? How long
would it take to reach that speed?
ANSWER:
If the ball were a
large distance from the earth (essentially infinite) the speed it would
acquire when it hit the surface of the earth would be equal to the
escape velocity, the speed a projectile shot straight up would have to
have to totally escape earth's gravity. Of course, it would take
infinite time to fall from infinitely far away, but if you were to drop
it from some distance r away from the earth you could calculate the
speed from energy conservation solving the following equation for the
speed v:
v2/2-MG/R=-MG/r where R is the radius of the earth in m, M
is the mass of the earth in kg, and G=6.67x10-11 (Newton's universal
gravitational constant). Calculating the time would be possible but
perhaps more involved than you want to get into!
QUESTION:
Is it
possible for something to orbit a black hole?
ANSWER:
Certainly.
In fact it is thought that there are binary star systems in which one
star becomes a black hole and the other continues orbiting. Eventually,
though, the orbiting partner will be sucked in.
QUESTION:
If
uranium has a greater binding energy per nucleon than helium 4, then why
is helium 4 much more stable?
ANSWER:
Because there are no decays
which are energetically possible for helium 4. There is just "nowhere
for it to go."
QUESTION:
If a mass of 10 kg compresses a spring
1m, then the spring constant k is 10/1 = 10N/m. And the elastic
potential energy stored in the spring is therefore 0.5 x 10 x 1 = 5J
(0.5kx2). However the gravitational potential energy lost by the mass is
mgh = 10 x 10 x 1 = 100J. I thought these two amounts of energy should
be the same. No other energy is added or removed. It is probably obvious
but I'm stumped. What am I missing here?
ANSWER:
You have several
things wrong. First, the weight of a 10 kg mass is 10x9.8=98 N, so that
is the force which the spring exerts to keep the mass in equilibrium at
a compression of 1 m. So, k=98 N/m. The energy of the compressed spring
is now 49 J. Now, what is the gravitational potential energy? It is
whatever you want! The gravitational potential energy is always
arbitraty to within an arbitrary constant and so you may choose the
level of zero gravitational potential energy to be anywhere you want:
If you choose y=0 where the mass is now, then the total energy of
the system is 49 J+mgy=49 J.If you choose y=0 where the mass was when
the spring was not compressed, then the y=-1 m total energy of the
system is 49 J+mgy=49 J+10x9.8x(-1)=-49 J.If you choose y=0 to be
halfway between, then y=-1/2 m total energy of the system is 49 J+mgy=49
J+10x9.8x(-0.5)=0 J.My advice is not to memorize mgh but mgy which
emphasizes that there is no magic place where h=0.
QUESTION:
When an alpha particle moves through an atom it will leave the atom
undeflected if it is far enough away from the nucleus. What interactions
are there with the electrons? Why do the electrons not attract and
therefore deflect the positive alpha particle?
ANSWER:
Most
certainly the alpha particle interacts with the electrons. But, the
alpha particle has a mass about 8000 times bigger than the electron so
it is like throwing bowling balls at bb's--the bowling ball is deflected
only a miniscule amount. However, this is the mechanism by which alpha
particles lose their energy going through matter; they have many
collisions with electrons giving each electron a tiny amount of energy
but eventually lose a large fraction (or all) of their energy. As you
probably know, alpha particles don't go very far in matter--even a piece
of paper can stop an alpha particle of a few thousand volts of energy.
QUESTION:
During a radioactive decay, when an electron is emited by
the nucleus the overall charge on the nucleus must be positive, since
there one more proton than before, why do equations not include the
positive sign?
ANSWER:
I am not sure I know what you mean by the
equations not including a positive sign. Here is what happens in
negative beta decay: if the nucleus has too many neutrons and too few
protons to be stable (somehow it knows!) and so one neutron
spontaneously turns into an electron, a proton, and a neutrino. The
electron and the neutrino are ejected and the proton stays behind in the
nucleus. So electric charge is conserved, that is the remaining proton
and ejected electron have zero net charge (the neutrino is uncharged)
and the original neutron had zero charge. The atom left behind, however,
has one too few electrons so it is a positive ion. There is also another
kind of beta decay in which the nucleus has too many protons and too few
neutrons to be stable; here one of the protons changes into a neutron, a
positron (the antiparticle of the electron and with positive charge),
and neutrion. Here the atom is left with one too many electrons, that is
it is a negative ion.
QUESTION:
Imagine a lightsource (i.e
Flashlight) located someplace incredibly far away from me, the space
between the lightsource and myself is empty and there is nothing else in
the universe. Once I turned the light on, would I eventually get to see
the light no matter how small the source is, or would the light "wear
out" at some point?
ANSWER:
It certainly never "wears out". But
whether or not you can detect it depends on how intense it is, how far
away it is, and the nature of the source. The simplest source to think
about is a point source the intensity of which falls off like 1/r2.
Eventually, we will be far enough away that the intensity becomes so
small that we must think of the light as photons instead of waves. The
intensity will then be very few photons per second per square meter. In
principle, though, as long as you made a very big detector capable of
detecting a single photon and waited long enough, you would eventually
see one. If you used a laser instead of a point source, the light would
not fall off strongly with distance and, provided that your detector
intercepted the beam, you would easily be able to detect it. However, no
laser is really perfectly collimated and the comments for the point
source would be applicable to some extent for large distances.
QUESTION:
Is there an upper limit as to how hot ordinary matter can
get? Since temperature is really the average energy of the particles of
matter, it would appear that eventually the average speed of the
particles would approach the speed of light. Since nothing can go faster
than light, what happens to super enegetic particles when more and more
engery is applied to them? Do they get more massive? If so, at what
temperature do these relavistic effects become significant?
ANSWER:
Although there is an upper limit to the speed a particle can have, there
is no limit to how much kinetic energy it may have (because kinetic
energy is not mv2/2 in relativity). For example, a particle with speed
0.9999 of the speed of light has ten times the kinetic energy as a
particle with speed 0.999 the speed of light (only 0.1% slower).
QUESTION:
I recently read an essay written by Lee Smolin and he
stated that protons and neutrons have the same mass, yet a neutron is
heavier. Now it is my understanding that if any two things have the same
mass then they have the same weight. So, is it possible that
electromagnetism or weak force have an affect on gravity's pull on mass,
thereby affecting the neutrons weight? If not, I am interested in your
theory.
ANSWER:
I don't know the context of the statement, but
unless you misunderstood his meaning, it is in the context of some
theory of quantum gravity in which mass and weight have different
meanings than in classical physics. You are right that we normally
specify that W=mg and so all particles with the same m should have the
same W.
QUESTION:
Why are electons considered negative? Is there
anything that makes them specificly negative or is that just the charge
that scientists assigned it?
ANSWER:
There is no good reason. All
the mathematics of electricity and magnetism would be just the same if
we called electrons positive. The important thing is that there are two
kinds of electric charge (unlike gravitational mass for which there is
apparently only one kind) and it is convenient to label one positive and
one negative. The convenience is in the mathematics; e.g., if the force
between two positive charges is repulsive, then so is the force between
two negative charges because the force depends on the product of the
charges. By the same token, the force between a positive and a negative
charge will be attractive. Incidentally, it was Benjamin Franklin who
originally labelled the the kind of charge which electrons happen to be
as negative (electrons had not been observed individually in his day).
QUESTION:
I'm wondering how much slower light travels in
non-vacuum environments, i.e. air, water, etc. Maybe you have a chart
comparing the medium that the light is travelling in to speed in
whatever unit, say % of c.
ANSWER:
There is a well known physical
constant called index of refraction, n. It is defined as n=c/v where v
is the speed in the medium. Some typical indices of refraction are air:
1.0003; water: 1.333; flint glass: 1.66; diamond: 2.42.
QUESTION:
Is electricity just magnetism at rest? Why do we treat electromagnetism
as two separate vectors?
ANSWER:
You might say that magnetism is
what happens when you put electricity in motion. You are right that we
should not treat electricity and magnetism as two different things since
they are really both parts of electromagnetism. We treat them separately
for two reasons. First, this was the historical development and it has
therefore become deeply embedded in the language of physics. Secondly,
the associated phenomena are much easier to understand mathematically if
we talk about these two vectors; the correct and rigorous way to discuss
electromagnetism is to use what is called the electromagnetic field
tensor, a single mathematical entity, but a tensor is a more difficult
concept to grasp. It is the nature of electromagnetism that it cannot be
fully described using a single vector field, but two vector fields can
contain the information which a single tensor field does.
QUESTION:
If light exhibits Doppler phenomenon, an observer during a "blueshift"
will measure photons of greater energy than are being emitted. How does
this phenomenon account for energy conservation?
ANSWER:
Suppose
that there is a stone at rest. It has zero kinetic energy. Now run by it
with a speed of v; now it has a kinetic energy of mv2/2. No puzzle,
right? The same is true of photons (except they cannot be at rest and
their kinetic energy is their whole energy and not mv2/2). There is an
important lesson here: the absolute amount of energy in a system is
always arbitrary to within an additive constant, it has no real meaning.
What matters is how energy changes (for example, if it doesn't change,
energy is conserved.)
QUESTION:
How would you find the speed
that the center of the earth is rotating when the outermost part of the
crust is spining x amount of kmph?
ANSWER:
The very center of the
earth has no speed (due to the earth's rotation) at all. If a point of
the surface of the earth at the equator has a speed V and the earth has
a radius R, then to find the speed v of a point a distance r from the
earth's axis of rotation, you would use the equation v=Vr/R. It is
important that it is the distance from the axis which determines the
speed. Therefore someone at the equator has a speed V but someone not on
the equator has a speed less than V and someone at the north or south
poles has a speed of zero.
QUESTION:
What would the effect on
the perceived gravitational pull of our planet if the rotation (or spin)
of the planet was increased by a factor of 4? I would assume that the
increased momentum at the outer edges would cause items on the surface
to experience a lower gravitational pull. Unfortunately, I can not
locate any equations to summarize this. Can you lend any assistance?
ANSWER:
The answer to your question depends on where you are. The
effect would be zero at the poles and maximized at the equator. I will
work it out for the equator. The first thing you need to do is calculate
your acceleration. Since you are moving in a circle, your acceleration
is v2/R=(2pR/T)2/R=4pR/T2=4x3.14x6.4x106/(3600x24/4)=0.17 m/s2; here v
is the speed of something on the equator, R is the radius of the earth,
and T is the period ("length of day" which you stipulate to be 24/4=6
hours). This is the centripetal acceleration and the direction is toward
the center of the earth. The sum of all forces on you must add up to
your mass (m) times this acceleration. The forces on you are your own
weight mg=9.8m (down) and the force that the ground exerts up on you,
call it N. So we have N-9.8m=-0.17m, or N=9.63m. The force N is the
force by which you perceive how heavy you feel, so you feel about 1.7%
lighter than if the earth were not rotating; if you were standing on a
scale, which measures the force you exert on it, not your weight, it
would read 1.7% smaller than your actual weight mg.
QUESTION:
What are independent variable and dependent variable.
ANSWER:
An
independent variable is one over which you have control in a particular
experiment. A dependent variable is one which depends on other
variables, one over which you do not have control. For example, suppose
you want to know how the length (dependent variable) of a stick depends
on its temperature (independent variable). Then you make measurements of
the length of the stick at various temperatures and then analyze your
data. The data analysis is often done by plotting the dependent variable
as a function of the independent variable.
QUESTION:
c is a
universal constant, why would this be? If light travels through
different mediums the velocity is changed, correct? Like when light
travels through a diamond, its speed is 88,000 mi/s. Is "c is a
universal constant" stating that c can never be exceeded? Please
explain, thanks!
ANSWER:
The universal constant is the speed of
light in a vacuum, not the speed of light. What the usual relativity
postulate states is that the speed of light in a vacuum is independent
of the motion of the source or the observer.
QUESTION:
Is empty
space granular? I'm asking because the more I read about the nature of
"nothing" - the more it seems like "something."
ANSWER:
I don't
think anybody really knows whether there is any limit as to how small a
volume can be.
QUESTION:
It's generally accepted that all
elements other than hydrogen were originally formed in the interior of
stars. But couldn't those elements be created when hydrogen atoms
collide outside a spinning black hole too?
ANSWER:
Anything which
would give atoms sufficient energy to overcome the Coulomb repulsion of
the nuclei could result in nucleosynthesis. However, anything other than
inside a star will result in a negligible amount of such material.
QUESTION:
why does a drop of water burn the very hot oil ?
ANSWER:
It doesn't. What happens is that the oil boils the water
which vaporizes.
QUESTION:
Is it possible to determine the
spring constant of a bush (pine) ? (We need to estimate somebodies
weight)
ANSWER:
A bush is a pretty poor approximation of an ideal
spring, that is the amount by which a particular weight would compress
it is probably not proportional to the weight (that is, a 200 lb person
would probably not compress the bush twice as much as a 100 lb person).
But, if it were a reasonable approximation of an ideal spring, you would
merely have to calibrate it by measuring the amount of compression x
caused by a known weight W. Then the spring constant would just be
k=W/x.
QUESTION:
I am a high school physics teacher with a
question concerning conductors. When a solid, conducting cylinder is
charged, the static charge will reside on the surface only. When that
same cylinder has moving charge (current), however, the current
distributes itself throughout the cylinder. Why the difference?
ANSWER:
First, there are two kinds of electrons on a conductor:
conduction electrons (typically on the order of one per atom) and the
remaining electrons bound to the atoms. Then one can either add or
subtract electrons to the material; this is the charge which, when
equilibrium is reached, must reside on the surface. Similarly, if you
put the conductor in an electric field, conduction electrons will move
around but they will eventually come to rest with charge residing only
on the surface. This is because if there is an electric field inside the
conductor the conduction electrons will move, that is they will not
remain at rest. Therefore, if you maintain an electric field inside the
conductor, electrons will move in response to the force they feel and if
you take them out on end and put them in at the same rate at the other
end, a steady current will flow through the conductor. This is what a
battery does: by maintaing a potential difference (voltage) across the
conductor it therefore maintains an electric field inside the conductor
which causes the charges to move. (It also acts like a "pump" removing
electrons from one end of the cylinder and moving them to the other.)
So, in electrostatics the whole conductor is at the same potential, the
electric field is only outside and perpendicular to the surface and all
charge resides on the surface; for a steady current a potential
difference is maintained which causes an electric field to exist inside
the conductor which causes conduction electrons to move through the
volume.
QUESTION:
I am not educated so please forgive me for the
simplicity of the question. I realise that mathematically perfect shapes
and flat surfaces cannot always exist in the natural world. If a perfect
flawless sphere rests on a perfectly flat surface how much of this
sphere is in contact with the surface? Does it matter how large the
sphere is? I would also like to know how much weight would be
concentrated at this almost negligible point of contact?
ANSWER:
A perfect sphere would be in contact with a perfect plane at only one
point. It does not matter the size of the sphere. The sphere would push
down on the plane with a force equal to its own weight (assuming the
sphere and the plane are at rest), and all this force would be at the
point of contact. The pressure on the plane, the force per unit area,
would be infinite since the area of a point is zero.
QUESTION:
If I were able to place two photon detectors in space, one a mile above
and one a mile below a hypothetical single atom that was just in the
process of emitting a photon, would both detectors be able to detect
said photon? In other words, is the direction an emitted photon travels
in arbitrary or is it somehow predetermined, or is this a case of the
famous wave/partical duality?
ANSWER:
Normally the emissions of
photons is isotropic, that is a photon is likely to go off in any
direction. But this is not because each atom is equally likely to emit
in any direction, but rather because the whole collection of atoms whose
radiation is being observed are randomly oriented. However, if the atoms
happen to be aligned in some way for some reason, the radiation pattern
will not be isotropic but will emit more intensely in some directions
than in others. That is because each atom is, in essence, a little
antenna and antennae have radiation patterns. Atoms usually have
electric dipole radiation patterns.
QUESTION:
why don't a roof
collapse from atmospheric pressure
ANSWER:
Because the pressure
also pushes up from the underside.
QUESTION:
Can water be heated
due to convection inside a satellite?
ANSWER:
The simplest kind
of convection, free convection, depends on the buoyant force to move the
fluid. Since the buoyant force is a gravitational effect, then in an
environment like a satellite there would be no convection. However,
convection has many other subtleties. You can get more information at
http://scienceworld.wolfram.com/physics/Convection.html
QUESTION:
I was wondering, if you can (in theory) use antiprotons in a rocket, why
can't you do it with say positrons, or antiquarks?
ANSWER:
You
could, but, having smaller mass each positron annihilation would release
far less energy. Antiquarks could not be used because we cannot isolate
quarks.
QUESTION:
Why does the period of a pendulum increase as
its lenght increases?
ANSWER:
Because when you solve Newton's
second law you find a frequency which decreases with increasing length.
The details may be seen at
http://www.kettering.edu/~drussell/Demos/Pendulum/Pendula.html
QUESTION:
If you are in an air-filled spaceship and you open the
door you are not sucked into space, the air inside rapidly expands out
the opening and you are pushed out, not pulled. A vacuum is not like
gravity, it does not pull or attract, something else has to push.
Suction is actually some other force pushing matter towards the area of
less density or pressure. For this reason, I say there is no force of
suction, it's a misnomer. The absence of mass is not a force, it can't
be. Decreasing mass or pressure doesn't create force, not for gravity or
air pressure or anything. "Suction" is like "centrifugal force", a
virtual force or an effect caused by other forces. Lift from an airfoil
is from air pushing up from underneath, low pressure over the wing is
not pulling it up. Which is not to say the leading and trailing edges
and upper side curvature play no role, they do. The air effects above
the wing work by increasing or enhancing the upward force on the bottom
of the wing. It's easier to push something one direction if the force
pushing back is less.
ANSWER:
Suction is a qualitative word, not
scientific nomenclature. You are right that the net force pushes you
out, a larger pressure on your back than on your front; similarly the
airplane--a smaller force down on top than up on the bottom.
QUESTION:
This year I was taking both AP physics and anatomy and
physiology together and found something which did not make sense. I
asked both of my teachers and they are both right in their aspect.
According to Bernoulli's equation, as a tube increases in diameter, the
pressure increases in the tube compared to a smaller diameter. But in
the circulatory system, when the diameter of the artery is decreased by
the buildup of cholesterol on the walls, the pressure increases. Also,
when I asked my mom, who is a doctor, she says to decrease the blood
pressure of a patient they give medicine which dilates the arteries.
This is the exact opposite of what they should be doing according to
Bernoulli's principle.
ANSWER:
I think the problem here stems
from the fact that blood is not an ideal fluid which is required for
Bernoulli to be right, nor is the contact between the artery/vein walls
frictionless. The more resistance there is to flow of the fluid, the
harder you have to push it to move it along. Hence, an artery with
deposits on it, while requiring the blood to move through with higher
speed and therefore lowering pressure due to Bernouli effects will have
a higher resistance to flow and require higher pressure to move it
through. I recommend your reading the selection in Wikepedia about blood
pressure.
QUESTION:
What determines the direction in which a
photon will go when we consider that it is perpendicular to fluctuating
electric and magnetic fields? What determines it will go forward or
backward?
ANSWER:
At some instant and at some point in space, the
electric and magnetic fields are perpendicular to each other. If you
take the fingers of your right hand and curl them from the electric
field to the magnetic field, then your thumb points in the direction of
propogation. I could not find a picture specifically for this, but the
picture to the right works if the green vector (labelled v) is the
electric field, the blue vector (labelled B) is the magnetic field, and
the red vector (labelled F) is the direction of travel of the wave.
(Also, q=90o.)
QUESTION:
Mike is going on a road trip. he's on
the highway moving at a constant speed in his car. he notices that
objects that he passes that are straight in front of him (the gravel on
the road, the white dashed lines) move fast (as fast as the car), and as
he begins to gaze sidewards, he notices that things don't move as fast
as the things right in front of him (the road signs seem to be moving
slower than the coke can right in front of him as he passes both). He
notices that this trend continues right down to the mountains 30 miles
to the side. they're are barely moving, if at all... Now you'll realize
that none of the objects are actually moving; it's mike that's moving.
everything is moving relative to him. is there any formula that can
measure the "speed" of these objects where the relatives speeds of
different objects, depending on their distance from mike?
ANSWER:
All objects at rest have the same velocity relative to Mike. But, the
appearance is what counts to him. A distant mountain will appear to be
the same size as a rock by the roadside. It takes the rock maybe 1/10 of
a second to "move" its own size but the mountain may take 100 seconds to
move its size. Hence, the mountain appears to be moving more slowly
because the apparent sizes are the same.
QUESTION:
Would it be
possible to get supplies to mars by creating a giant "pod gun" ? this
"pod gun" would use a contained explosion of hydrogen (much like a real
gun) to launch a "pod" of supplies into space.
ANSWER:
Any method
which accelerates an object to a velocity greater than the escape
velocity (the speed an object must have at the earth's surface to escape
earth's gravity) would work. Questions of practicality and cost would be
the determining factors.
QUESTION:
How do electrons leap from
one side of an atom to another without traversing the space in between?
ANSWER:
What makes you think that they do? The proper way to think
about an electron in an atom is to say that it is a probability
distribution, that is it might be anywhere with a certain probablility
being associated with each small volume in space. Hence you might make a
measurement and find that the electron is on one side of the atom and
later make a measurement and find it is on the other. This did not mean
that it went discontinuously from one side to the other.
QUESTION:
I would like to know if a magnet's pole can be neutralized by
insolationing or by anyother way .
ANSWER:
The only way to do
that is to superimpose it on the opposite pole of another magnet. The
important physical principle here is that the pole of a magnet can never
exist alone, it is always accompanied by an opposite pole.
QUESTION:
It is given that there are two masses (bowling balls for
instance) present in a vacuum. there are no outside forces acting upon
them. no gravity, no air resistance, nothing. Both masses (the bowling
balls) are the exact same shape and diameter. However, one has a mass of
10kg, while the other has a mass of 100kg. both objects are at rest
relative to us as observers. If two equal forces where applied to both
these objects at the same instant (say we put two identical rockets on
these bowling balls) and fired them for exactly the same amount of time,
would both objects go exaclty the same distance, or would one go farther
then the other, and if so, which one? And regardless of the answer, why
does this occur?
ANSWER:
You have hit on the central ideas of
Newtonian physics. First, after getting either ball moving by your
rocket, it will not stop after you turn the rocket off--it will keep
going forever, so the question of which ball goes farther is moot.
However, if you mean which ball goes farther during the time the rockets
are on, it is the less massive one. This is because Newton's second law
says that the acceleration of an object (the rate of change of its
speed) is proportional to the force it experiences divided by the mass;
hence, with equal forces the one with the smaller mass has the larger
acceleration. Hence for equal times the less massive ball will acquire
more velocity and hence go farther.
QUESTION:
Is it just arcing
that causes a transformer to explode? Is there some flammable material
(e.g. oil) inside it that causes the explosion? Seems like an arc would
make the transformer melt, not explode.
ANSWER:
There is
flammable material inside; if arcing occurs, there is likely a high
current inside which provides the heating necessary to ignite the
flammable material.
QUESTION:
Why do keepers of the famous clock
Big Ben in London add or remove coins from the bottom of the pendulum to
speed up or slow down the clock if the mass of pendulum has nothing to
do with the pendulum's period?
ANSWER:
Because Big Ben's pendulum
is not a simple pendulum, that is it is not a point mass attached to a
massless string. It is what is often referred to as a "physical
pendulum" and its period is determined by its moment of inertia and the
moment of inertia depends on how much mass there is and where it is.
QUESTION:
I have a theory that the movement of a body in the
universe is relative to other objects. Ergo, nothing can be absolutely
still. Do you agree that everything in the universe is moving, and that
no object is entirely at rest?
ANSWER:
If, as you suggest,
everything is relative, then "at rest" is a matter of definition. That
is, I can define myself, for example, to be at rest and then everything
else in the universe moves unless it happens, as my computer is right
now, to be at rest with respect to me. On a deeper level, nothing can be
at rest because of the Heisenberg uncertainty principle because you
cannot precisely know the velocity of something without being completely
ignorant of where it is.
QUESTION:
When I get out of a car while
wearing running shoes I get shocks from the metal door frame. However,
when I exit the vehicle while wearing insulated boots I do not get
shocks. My question is; All other conditions being the same, would I not
still carry a static charge that would be discharged when I contact a
proper ground? And why not?
ANSWER:
I am not sure what you mean
by insulated boots, but what you want to do is have a good electrical
contact between you and the ground when you get out. What is actually
happening is that you have a static electrical charge on you when you
get off the seat of the car. If you have shoes which have soles which
connect you electrically to the ground, the charge leaks off. If the
charge cannot leak off, it will seek a way to get off and will do so
through the car (which, in spite of the tires being rubber and appearing
to be not a good conductor, is actually a quite good path to ground).
Before you touch the door, there is a large voltage (thousands of
volts!) between you and the door because of your electric charge; this
voltage causes a spark to jump which hurts. The best way to defeat this
is to hold the door as you are getting out so the charge leaks off
without there being a spark. So, my suspicion is that your running shoes
have soles which insulate you from the ground but your boots do not.
Incidentally, the problem is greatest when the humidity is low because a
lot of water vapor in the air lets the charge leak off through the air.
QUESTION:
As a shotgun fires, the bb's make a pattern that gets
wider and less dense with more distance. So how can light leave a small
source and fill all the void in between for what seems could be an
indefinate distance? i.e. the sun
ANSWER:
Because a shotgun is
more like a flashlight than the sun. The light from a flashlight is
pretty well collimated and spreads a little. The light from a source
like the sun goes out in all directions. However, the intensity of the
light from this kind of source gets smaller as you get farther away
quite rapidly--if you go 10 times as far away, the intensity of the
light gets 100 times smaller. That is why, of course, star appear much
dimmer than the sun even though the sun is a pretty average star.
QUESTION:
if heat is the vibration of atoms why doesn;t it feel
like vibrations but well heat?
ANSWER:
The vibrational frequency
of a typical atom in a room temperature solid is on the order of 10 THz,
that is about 10 million million vibrations per second. To put this
frequency into perspective, you cannot hear more than about 20,000
vibrations per second. Your body has no mechanism by which it can
respond to such a rapidly changing stimulus. Furthermore, the vibration
of a single atom against your skin would be imperceptible and the atoms
are all vibrating with random phases.
QUESTION:
if gravity is
approximated by a constant and if the frictional force is proportional
to the velocity, show that a free-falling body (i.e. no restoring force)
approaches a terminal velocity
ANSWER:
Since the downward force
is mg (constant) and the upward force is bv (b is constant, v is speed),
the net force will be mg-bv down. The frictional force starts at zero
but as v increases the net force gets smaller. Eventually the speed will
be big enough that the net force will be zero, so the speed will remain
constant. The terminal velocity will be mg/b.
QUESTION:
If you
wanted to use your laser beam to hit a space station that was traveling
above the atmosphere and just above the horizon, would you aim the laser
above, below, or directly at the station YOU SEE FROM EARTH? (the index
of refraction of space is exactly 1.0, while the index of refraction of
air is about 1.001)
ANSWER:
Since light is reversible, that is
light traveling from you to the space station will follow the same path
as light traveling from the space station to you, you should visually
aim at it.
QUESTION:
Hi, quick question, a few friends and I had
a little debate the other day. Basically the premise of the debate was
that if humans somehow started to dump all our garbage into space the
mass of the earth would be affected enough to somehow affect earth's
orbit. Their contention was that everything is produced by the earth as
in what humans make from it therefore if we started jettisoning it into
space it would affect earth's mass to alter its orbit however miniscule.
I saw something really wrong with this, in my view there are many
variables not being taken into account here that affect earth's mass and
its relation to the sun and its orbit and that garbage is too small a
variable or another counteracting variable would negate any effect it
could have if it was sent into space. Yes a little bit of a weird topic
lol, but any insight would be appreciated.
ANSWER:
If the earth's
mass suddenly decreased by half, the period of the orbit (one year)
would be totally unaffected. The period of the orbit of a satellite is
independent of its mass if the sun's mass is very large compared to the
earth's mass (2x1030 kg vs. 6x1024 kg, a ratio of about 3/1,000,000). To
be exact, it is the reduced mass of the system which matters; that would
be msunmearth/(msun +mearth), but, since msun>>mearth, the reduced mass
is incredibly close to mearth, and the dependence of the orbit on the
mass is completely negligible. Technically, however, your friends are
right that a change of mass will affect the orbit; it is just that for
even a huge change in mass (a large fraction of the earth's total mass)
the effect would be so small as to be unmeasurable.
Another problem
to consider is the possible disruption of the earth's orbit because of
how the mass was ejected. For example, in the extreme case where you
jettison half the earth's mass into space with some velocity the
remaining half would recoil with the same velocity which would certainly
seriously alter the orbit. But if you jettisoned a million tons, the
earth's recoil would be negligible.
QUESTION:
;
can you please
explain nutrinos in basic terms?
ANSWER:
Many radioactive nuclei
undergo a decay called beta decay. One kind of beta decay happens if a
nucleus has too many neutrons (which have no electric charge). Somehow
nature knows this and takes one neutron in the nucleus and turns it into
a proton; but electric charge must be conserved, so the appearance of a
positively charged proton necessitates the creation of a negatively
charged particle, so an electron is ejected from the nucleus. It is this
electron which is the "radioactivity". Back in the 1930s when beta decay
was first discovered a most disturbing thing was observed: the electrons
which were ejected came out with a broad range of energies. This was
disturbing because each electron left behind the same thing (that is a
nucleus with a particular amount of energy), so the range of electron
energies implied that the energy was not conserved by beta decay. This
principle, energy conservation, is so dearly held by us physicists that
we invented a third particle, the neutrino, which had no mass and no
electric charge and carried off the right amount of energy to insure
that energy was conserved. A remarkable fact is that, because it
interacts so incredibly weakly with matter, the neutrino was not
experimentally observed until the late 1950s. So nearly 30 years elapsed
before this hypothesized particle was observed, yet no self-respecting
physicist doubted its existence!
Neutrinos have been in the news
lately because of the so-called "solar neutrino problem". We believe
that we understand very well what goes on inside the sun and yet the
number of neutrinos which we observe on earth is considerably fewer than
the number predicted by our models of stars. This problem has recently
been solved by measurements which find that the neutrino is not really
massless but has an extremely small mass (much smaller than the
electron, the lightest of "everyday" particles). I will not attempt to
explain how this solves the puzzle, but it does!
QUESTION:
Does
gravity have a speed at which it travels? To clarify, if you teleported
two objects to some incredibly far away & empty region of space, so the
only noticeable force of gravity would be the two objects pulling each
other together, upon arrival by teleportation like "popping in to
existence" would there be a delay before they begin pulling each other?
ANSWER:
I do not believe that the speed at which a gravitational
field propogates has ever been measured. It is generally believed to
propogate with the speed of light. But whatever its speed actually is,
nobody would believe that it is instantaneous.
QUESTION:
I have
some demonstration capacitors that are rated 1F at 5V. Is this correct
then that it can hold a static charge of 5C? I've always thought that 1C
of static charge was enormous. Am I missing something? Is there a
dielectric out there that allows this?
ANSWER:
Those capacitors
could not possibly be 1 F. They are probably 1 mF.
QUESTION:
Is
a satellite that is orbiting earth (and not decaying in its orbit) in
equilibrium? I say no, because only 1 force (gravity) is acting on the
satellite--otherwise it would move in a straight line. My coworker says
that inertia or momentum is balancing the gravity and that therefore the
satellite is in equilbrium. What is the real answer?
ANSWER:
You
are right. It is clearly accelerating (velocity always changing
direction) and so cannot be in equilibrium.
QUESTION:
Is there
a way to change/slow down the rate of radioactive decay...for example,
Tc99m half life is 6.01 hours. Is there a way to change that time, or
slow it down?
ANSWER:
Not unless you slow down time itself, for
example if the radioactive nuclei had a very high speed in the
laboratory, they would live much longer because of time dilation.
QUESTION:
in my gcse physics lesson the teacher explained that an
electron is given out by a nucleus when it changes during beta decay and
a nuetron changes into a proton. Why is the electron made when the
neutron changes? also is there such a thing as anti elements for example
the exact opposite of hydrogen?
ANSWER:
There is also a third,
chargeless particle, the neutrino, which is a product of neutron decay.
It is not simple to answer a question like why the electron is ejected;
that requires understanding the theory of beta decay (that is what this
is called). One easy way to believe that an electron might come off is
that the total electric charge of the universe must remain constant,
that is you cannot create or destroy electric charge. If a proton
appears, so does 1.6x10-19 Coulombs of charge; to keep the total charge
equal to zero, -1.6x10-19 Coulombs of charge must appear which just
happens to be the charge of an electron. And yes, antihydrogen
(consisting of an antiproton and a positron) has been observed. Check
out this story from CERN.
QUESTION:
Quantum mechanics views
force interactions between particles as an exchange of other particles,
such as the photon. General relativity views the gravitational 'force'
as an artifact of space-time distortion. How does general relativity
handle the other 'forces' - electromagnetic, weak and strong? Does
general relativity also view these forces as manifestations of
space-time distortion? Or, does it view gravity as a special case
distinct from these forces?
ANSWER:
Some work has been done in
extracting electromagnetism from the equations of general relativity
with mixed results. It is pretty fair to say, however, that gravitation
and all other forces of nature are not reconciled. A theory of "quantum
gravity" is one of the "holy grails" of theoretical physics.
QUESTION:
I have seen many warnings about the possibility of a
hydrogen explosion when charging batteries. I know hydrogen is produced,
but the volume in the battery seems small, many have a method of venting
and the ignition source is outside the battery. Are there any scientific
studies that confirm the culprit is hydrogen? I have been looking on the
internet but have had no luck finding an authoritative source.
ANSWER:
Hydrogen is very dangerous, even in small amounts if
confined. Venting makes the danger less acute but not nonexistant.
Explosion is a relatively rare event with batteries, but not to be taken
lightly.
QUESTION:
Is it possible to heat water vapor to a
plasma state? Can it be done on earth?
ANSWER:
Any gas may be
converted into a plasma (which is just a mixture of unbound electrons
and positive ions). My guess is that water would probably dissociate
into H and O either before or simultaneously with ionization. It doesn't
take all that much energy and could easily be done on earth.
QUESTION:
If I tear a piece of paper, what is happening at the
subatomic level at the torn edges? Are the electrons/subatomic particles
getting ripped out of their positions? And then do they fly off into the
air or remain glued to their original position?
ANSWER:
Solids
hold together by adjacent atoms bonding to each other. Ripping a piece
of paper simply breaks these bonds. This will be a pretty violent
process on the microscopic level and some atoms and clusters of atoms
are sure to end up leaving the paper altogether.
QUESTION:
My 7
year old daughter has a "simple" physics question, but I want to give
her a precise answer in terms she can understand. I am hoping you can
help. Here it is: At sea level, would a soccer ball which is completely
deflated (and collapsed) have a greater or lesser weight (as measured on
a standard scale) than one filled with helium? My supposition is that
the scale weight goes down when filled with helium, even though the
overall mass is increased by the helium itself. Is this correct? That's
a concept she can't understand and I want to explain it if possible.
ANSWER:
Your question has an ambiguity in it: you ask about the
weight "as measured on a standard scale". However, a standard scale does
not necessarily measure the weight of an object sitting on it, it
measures the force you push down on it with. So, a 10 pound weight on
the scale and on which you are pulling up with a force of 4 pounds will
only "weigh" 6 pounds according to the scale. So, let me address the
question in two parts.
Which has more weight, the empty ball or the
full ball? Obviously, the full ball since it has the weight of the ball
plus the weight of whatever it is filled with.Which will have the
greater apparent weight as measured by the scale? Here a new force, the
buoyant force, comes into play. When you put an object into a fluid (air
is a fluid) there is an upward force on it which is equal to the weight
of the displaced fluid. Since you are dealing with a 7 year old, just
give her a simple example of a buoyant force: e.g. a soccer ball filled
with air on the bottom of a swimming pool pops to the top because of the
buoyant force; the buoyant force on the soccer ball in air is just less
than in water because water is more dense than air. So, assuming that
the helium is at a pressure (close to atmospheric) not too high, there
will be an upward buoyant force (equal in magnitude to the weight of an
equal volume of air) greater than the weight of the added helium, and so
the apparent weight will be less than the empty ball.
QUESTION:
I am
having trouble reconciling these two principles: (1) the velocity of
light is independent of the velocity of the source, and (2) in a
uniformly moving system you can't tell how fast you are going. Suppose
you are in a uniformly moving system and you set up a light source that
sends out two beams simultanously--one in the direction of the motion of
that system and one in the opposite direction. You have two detectors
located at equal distances from the source (thus detectors and source
are in a straight line). Wouldn't the detector located "behind" detect
the light before the detector located "ahead"?
ANSWER:
To
understand relativity, you have to "believe" the postulates. Essentially
what you must accept, as nonintuitive as it may seem to you, is that the
speed of light is the same as seen by any observer. The result of this
assumption totally upsets our ideas about what space and time are. The
experiment you describe is one of the classic examples illustrating how
the notion of time is different. The concept is that of simultaneity:
classically, if I determine two events to happen simultaneously, I
expect anybody else in the universe to agree with me. (Note that
"determine" is different from "see": if I see one event and then one
year later see a second event, but the second event happens somewhere a
light year from the first, then I determine them to be simultaneous.)
The experiment you describe will have an observer on the moving system
see the events happen simultaneously but an observer at rest will see
the two events to be not simultaneous in the way you describe. It is an
inescapable consequence of the fact that the speed of light is the same
as seen by any observer.
QUESTION:
We all know carbon dioxide
sublimes as "dry ice". Is the same true for carbon monoxide? Both have a
triple point. I've read conflicting things and was hoping you could
provide a definitive answer. And if not pressurized liquid gas released
and evaporating into a solid, how then is frozen or solid carbon
monoxide possible?
ANSWER: (provided by S. P. Lewis)
Whether or
not a solid in equilibrium sublimes to the gas phase as temperature or
raised, instead of melting to the liquid phase, depends on the
(presumably fixed) pressure at which the experiment is done, relative to
the triple point of the substance. If the experiment is done at a
pressure below the triple point, then a constant-pressure line in a P-T
phase diagram crosses the solid-gas coexistence curve. This means that
raising the temperature of the solid eventually leads to sublimation.
Conversely, if the operating pressure is above the triple point, then a
constant-pressure line crosses a solid-liquid coexistence curve and a
liquid-gas coexistence curve. This means that raising the temperature of
the solid eventually leads to melting, and further heating eventually
leads to boiling. For carbon dioxide, the triple point is at pressure
5.2 atm and temperature -57 C. If we assume the experiment is done at
ambient pressure (i.e., 1 atm), then we would expect solid CO2 to
sublime to gaseous CO2, which it does -- hence 'Dry Ice'. The triple
point of carbon monoxide, however, is at pressure 0.15 atm and
temperature -205 C. Ambient pressure is well above the triple-point
pressure, and therefore, under these conditions, solid CO would not
sublime on being heated. Rather, it would melt and then eventually boil.
QUESTION:
Would the shape of a balloon (i.e., regular 9" round;
oblong 9") with the same amount of helium affect the rate of ascent? I
would greatly appreciate your answer/input and any specific guidance
that you can offer us. We have read your groundrules and are not using
"The Physicist" to do our homework. In order to answer this question, my
son and I have been researching topics such as hot air balloons and
gravitational force by visiting our local library. However, our library
is very limited and provides few good science books. Therefore, we have
been performing various topic searches through Google during the past
several weeks in order to answer this question ourselves.
ANSWER:
There are several things to consider. I would like to just answer your
question without the complications of what happens at distances high
above the ground where temperature is much colder and pressure (of the
atmosphere) much lower. In first approximation, the only things which
will determine the motion of the balloon are the mass and volume of the
baloon+helium,; let's call those m and V respectively. The weight of
this balloon is therefore W=mg where g is the accelleration due to
gravity; this is a downward force. Now, Archimedes' principle tells us
that there will be upward force (buoyant force) equal to the weight of
the displaced air, B=rVg where r is the density of air. The total force
on the balloon is therefore B-W=rVg-mg upward. Because of Newton's
second law, the balloon will therefore have an upward acceleration of
a=(rV/m-1)g which is independent of its shape. However, in the real
world there is another force which cannot be neglected and that is the
air friction the balloon experiences when it starts moving. This depends
in very complicated ways on the geometry of the balloon and is best
studied experimentally, I think.
QUESTION:
The triple point of
Hydrogen is about 13.8 K and the temperature of Universe is about 2.73
K. This means that all the Hydrogen atoms in the universe must be in
solid state. Why don't these tiny particles coalesce and form a hyge
ball of solid Hydrogen, weighing about 10 to the power of 49 or 50 tons,
which would then implode under its own mass and lead to another Big
Bang? Would this scenario ever take place?
ANSWER:
No, it does
not mean that the universe is solid because the pressure of the
intergalctic medium is incredibly small. Hence the intergalactic medium
is essentially gaseous hydrogen.
QUESTION:
I am a senior high
school student, and I have a question pertaining to thermodynamics
(actually originating in my chemistry class). My teacher asked us the
following question "Which has more heat: 1000g of water (heat capacity
of 4.18J/°Cg) at 60°C or 1000g of steam (heat capacity of 2.01J/°Cg) at
105°C?" First of all, I was under the impression that heat is defined as
the transfer of energy during a reaction, and that objects don't have a
property called "heat". Presumably, he was looking for the substance
which had the greater internal energy. In this case, I would answer that
the steam had the greater internal energy, since it had (presumably)
been heated as a liquid, then boiled and then heated some more to its
final temperature. Thus, it would have greater average kinetic energy,
and greater intermolecular potential energy than the water. I realize
that some complexity arises from the state change and pressures/volumes
etc. in gases, but I'm not sure exactly how. If you could shed some
light on this, it would be greatly appreciated.
ANSWER:
Your
semantics are sound, i.e. you should be thinking about internal energy.
Your reasoning seems sound also since you need to add energy to heat the
water, add energy to vaporize it, add energy to heat the steam.
QUESTION:
We are taught that E fields, M fields and EM fields are
real entities and that they contain an energy density; and that (changes
in) their influence propagate at lightspeed. There is an equivalence of
mass and energy, and energy must be conserved. If these statement are
all true, why is the mass of charged matter (e.g., an electron)
constant? Does there not exist a continuous flow of energy radially
outward from a static charge, for example, as the influence of its
electric field propagates to ever larger volumes of space?
ANSWER:
Because a field has an energy density does not imply that energy flows.
In fact, if you compute the rate at which energy leaves a volume
surrounding a static charge, the answer is zero. Charges radiate energy
only when they accelerate and the energy loss is taken from the kinetic
energy of the accelerating particle, not its rest mass energy.
QUESTION:
I read that electrons at SLAC are accelerated to speeds
of 0.999 999 999 948c. What are the specific products when electrons
moving at this speed collide with other particles? Could you list some
of the reactions produced at this speed? I would also like to know the
applied EMF in volts needed for achieving the above speed, so that I can
determine the energy of the accelerated electrons.
ANSWER:
The
huge number of possible reactions depending on the target make it
impossible to answer your first question. However, you second question
can be answered pretty easily. However, you want to calculate the total
energy E from the speed from which you can infer the voltage which must
have been applied. The total energy is E=mc2/[1-v2/c2]1/2. The
arithmetic is a little tricky for v so close to c, but I find that E=4.9
GeV. This is the total energy, so to get the kinetic energy you must
subtract the rest mass energy; but the rest mass of an electron is about
0.511 MeV=0.000511 GeV, so it is negligible. Hence, the EMF you seek is
about 4.9 x 109 volts.
QUESTION:
when you see a rainbow, you
always see part of a circle. How high must you rise to see the full
circle? Please include some references in your reply so that I can learn
more about this fascinating topic.
ANSWER:
There is a pretty
clear answer to your question at
http://www.wonderquest.com/rainbow-circle.htm.
QUESTION:
my
question to you is: "Where do the bubbles in softdrinks like coka cola
go in zero gravity?" Will they rise to the surface, or will they stay in
the same place? If so, will the bubbles keep growing? I can imagine that
mass matters, that the bubbles in a mass of soda the size of a planet,
'would' rise to the surface, but how about smaller masses.
ANSWER:
Bubbles rise because of the buoyant force. But, in a no-gravity
situation, there is no buoyant force. Therefore the bubbles should not
move at all. I guess the whole ball of softdrink would become a froth of
bubbles eventually but the evolution would probably be complicated to
describe.
QUESTION:
OK. I have been thinking about this for a
very long time, however since i do not possess the intimate knowledge
that a well-versed person in the ream of physics might have. My question
is this: From my understanding, there are four main forces which keep
the universe together. One of them is gravity. Gravity affects the
heavens and all that it encompasses even light. Light is bended by the
gravity exerted from a massive object. From what ive learned, this is
one way black holes are observed. As is commonly known, nothing can
escape the gravitational pull of a black hole, not even light. So what
we have are two extremes: in one extreme, a beam of light would travel
(theoreticlly) in a straight line if no force of gravity was imposed on
it and in the other extreme, light is bended so far that it is
incapapble of escaping when it enters a supermassive graviational field.
The question i have is is there a medium between the extremes? Would it
be possible for a beam of light to orbit an object of a specific mass,
trapping it in orbit?
ANSWER: (answer provided by L. A. Magnani)
Yes, light can orbit around a black hole of any given mass. The key
question is, how far from the singularity can the light maintain a
circular orbit? It turns out that, according to General Relativity,
light can maintain a circular orbit at 1.5 times the Schwarzschild
radius from the singularity (the Schwarzschild radius is 2GM/c2 where M
is the mass of the black hole, G is the gravitational constant and c is
the speed of light. This region is sometimes called the photon sphere.
Inside 1.5 times the Schwarzschild radius, no circular orbits exist; all
orbits are unstable and all objects moving inside of this distance fall
into the black hole.
QUESTION:
Two identical balls are attached
together with a 3-foot length of string. Hold one ball and allow the
other ball to stretch out the string. If the "system" is dropped from a
height of about 5 stories, why do the balls come together before they
hit the ground?
ANSWER:
The only explanation has to be air
friction. The leading ball behaves like a freely falling ball which
accelerates until it reaches its "terminal velocity"; it does not
continue accelerating because there is an upward force due to air
friction on it and this force gets bigger as the velocity gets bigger.
The upper ball, however, is in the wake of the lower and therefore has a
smaller air friction force on it.
QUESTION:
Ok, I have a friend
of mine that thinks if (in a vacuum with no gravitational interference)
you were in a spaceship and turned the rockets on you would begin
accelerating and continue to accelerate even after the rockets were
turned off. I thought that according to F=ma or a=F/m you would stop
accelerating and only maintain the velocity you had attained at the
moment you turned the rockets off. Is my thinking flawed or did I read
Newtons laws correctly?
ANSWER:
Your friend is dead wrong.
QUESTION:
I am trying to vibrate a tissue with a sound source that
is directed at the tissue, but not in direct contact with the tissue. I
have been told that using acoustic waves will provide this type of
push/pull motion. That is, they will push the tissue and actually pull
it back to equilibrium, as opposed to just allowing the tissue to come
back to it's equilibrium position on it's own before the next wave hits.
I have also heard that ultrasound waves do not have this property. That
is, they result in static displacement and will not allow the tissue to
return to equilibrium unless the source is off (as is the case in
pulsing ultrasound). A co-worker told me this was not true about
acoustic waves. Example the front of a speaker only vibrates in and out
because the membrane comes to rest on it's own before the next
vibration. Can you tell me the properties of these waves in this kind of
situation and maybe a source of information?
ANSWER:
There is no
simple answer to your question. Essentially your question has to do with
driven oscillations. If we model the tissue paper as a simple harmonic
oscillator (which you seem to be implying), then it has a characteristic
natural frequency. If you drive it with a frequency equal to that
frequency, it will have a large amplitude of oscillation with a
frequency close to its natural frequency (this is called resonance).
But, if you drive it with a different frequency, the paper, after some
initial transient behavior, will oscillate with the driving frequency,
not its natural frequency. The farther you are from the natural
frequency, the smaller the amplitude of the response will be.
QUESTION:
I have to do a physics project. Its called an egg drop.
We can only use a brown lunch bag, 3 straws, the card board of a toilet
paper roll and tape to create a device that will deliver our egg safely
to the ground from 4 diffrent hights. Do you have any design tips or
suggestions?
ANSWER:
I will not try to design something, but I
will tell you what you need to do. To break an egg you must deliver a
force to it. Force, according to Newton's second law is mass times
acceleration. So, since you have no control over the mass of the egg,
you must minimize the acceleration which it experiences to minimize the
chance of its getting broken. To do this you maximize the time it takes
for the egg to come to rest. Another issue (besides the magnitude of the
force on the egg) is how that force is distributed: an egg dropped on a
nail is much more likely to break than if you could take the force
exerted by the nail point and redistrubuted it over a bigger area of the
egg's surface.
QUESTION:
Lets say as an example that the muzzle
velocity of a particular rifle is 700 miles per hour. If you fired the
gun on an aircraft that had a constant velocity of 700 miles per hour,
would the velocity of the bullet relative to nature be 1400? My next
question is if you fired the bullet backwards, would the bullet's
velocity be Zero (relative to nature, not the aircraft)?
ANSWER:
Yes and yes, assuming that we neglect air resistance.
QUESTION:
I understand the "electron gas" model of metal, but one thing I've never
heard addressed is what happens at the surface of the metal. In a
simplistic model, we say: An electron travels some distance until it
collides with something. After the collision, it starts a new path in a
random direction. If an electron starts near the surface of a piece of
metal, and travels towards the surface such that its trajectory would
take it outside the metal before it collided with something, what
happens? Does the electron temporarily leave the metal before being
pulled back by electric forces? Can a collision with the surface be
treated as one of the other collisions where the electron starts a new
path in a random direction? Or should this be treated as an elastic
collision, as if the electron were a ping-pong ball bouncing off a wall
(angle of reflection = angle of incidence, etc.) ?
ANSWER:
Perhaps it is best to just examine the problem more classically. If an
electron comes shooting out of the surface (which it might), it will
have a positive image charge inside the metal which will attract it
back. On a more microscopic level, if an electron is removed, an equal
amount of positive charge is left behind which will attract it back. If,
however, the metal is very hot so that there are electrons of sufficient
kinetic energy to escape, then electrons will flow out the surface; this
is called thermionic emission. I think you should not think of a
"collision with the surface"; the electron either collides with
something close to the surface (which is, at a microscopic level, not
well defined) or it doesn't.
QUESTION:
I read somewhere that
tachyons can go faster than light. How?
ANSWER:
Tachyons are
hypothetical particles. A tachyon has never been observed. The theory of
relativity does not forbid particles to have a speed greater than the
speed of light, but you "cannot get there from here", that is you cannot
take a particle with speed less than the speed of light and accelerate
it to a speed greater than the speed of light.
QUESTION:
Is it
possible that the gravitational constant varies with the composition of
the mass? For instance, could a kg of ice have a slightly different
gravitational constant than, say, a kg of iron?
ANSWER:
Of course
no scientist likes to say "impossible", but in some sense the very name
"gravitational constant" automatically insures that what you ask is
impossible by definition. Then, since the only other things that
gravitational force depends on are mass or distance between attracting
objects, if you get a force different than what you expected, then you
probably made an error in measurement of mass or distance; the
gravitational constant is simply the proportionality constant in
Newton's universal law of gravitation.
QUESTION:
Hello, I have
been trying to find out how to calculate the force on an object when
this object is rotating around a point. I know that this is called the
centrifugal force and that it is calculated by [F = r * m * v2].
However, every place I look will not give me units of measurement. Is
the Force(F) in Newtons? is the radius(r) in Meters? is the mass(m) in
Kilograms? Is the angular velocity(v) in revolutions per minute? Thanks
a bunch
ANSWER:
First of all, it is not called centrifugal force,
it is centripetal force, a force pointing toward the center of the
circle (from the Latin centrum=center + petere=to seek). A centrifugal
force (from the Latin centrum=center + fugere=to flee) points away from
the center and is what phyicists call a fictitious force, i.e. it does
not exist. Secondly, the force is not what you have it but rather
F=mv2/r. Now the units are correct, (kg m2/s2)/m=kg m/s2=N.
QUESTION:
How can an particle, in real life have a net mechanical
energy of less than zero? Energy can be taken away from a system
resulting in a negative change in energy, but how can its total
mechanical energy be less than zero. I tried to justify this question
with the fact that potential energy is often relative, such as in the
case of gravitational potential energy, so all of the movement of a
particle happens "below" this zero reference point. But I am still
feeling unsettled about this. Is there a better answer?
ANSWER:
Only kinetic energy is definitively positive. Potential energy is always
arbitrary within an additive constant. What really matters is how energy
changes, not what energy is.
QUESTION:
A photon travelling from
a distant part of the universe is red-shifted by the time it reaches
earth. The photon has less energy when it arrives. Where has the missing
energy gone?
ANSWER:
For starters, you should not talk about
photons and gravity simultaneously since quantum mechanics and general
relativity are not compatible with each other. But the fact remains that
a photon leaving some very large mass will be red shifted so energy has
been lost. The source of the gravitational field will gain that energy.
QUESTION:
Has the idea that the speed of light is actually slowing
down been debunked? Do both gamma rays and radio waves move at 183,000
mps? If I turn on a light bulb in outer space will the EM radiation from
that bulb ever stretch out to the point of being below the visible
spectrum? Will it become infrared then microwave then radio wave?
ANSWER:
The question of whether nature's constants are in fact
constant over very long times is a question of interest to physicists.
There is no evidence that the speed of light is not the same as it has
always been. Electromagnetic radiation of a particular wavelength moving
through empty space will maintain exactly the same wavelength regardless
of the distance from the source.
QUESTION:
If you have a ballon
filled with helium and you let it go it will rise. As altitude
increases, air pressure decreases and the ballon expands. But as
altitude increases, temperature decreases and causing the ballon to
contract. Will it pop?
ANSWER:
The drop in pressure plays a more
important role than the decrease of temperature, so it will want to
continue to want to expand going to higher altitudes. However, whether
it pops and when are determined by things like what the balloon is made
of, how much helium was initially in it, etc.
QUESTION:
I was
just wondering, positrons and anti-protons have the opposite charges of
electrons and protons and anti-neutrons have the opposite charge of
neutrons. But I was under the impression that neutrons have zero
charge...so a negative neutron would be the same as a normal neutron..
What's the difference!?
ANSWER:
The antiparticle of a neutral
particle is also neutral. But they are not the same particle since there
are other quantities besides electrical charge which determine the
properties of an elementary particle.
QUESTION:
Last summer I
was paddling my canoe on an Ontario lake at late evening. The air and
water were almost perfectly still. I was smoking a pipe, and as I
paddled I obviously exhaled regular puffs of smoke. But when I looked
beside me, I noticed that the more or less coherent clouds of smoke were
travelling along with me at almost the same speed as the canoe! In fact,
they formed a very shallow arc sweeping away beside me and downwind from
the very slight breeze. But how is this possible? Why wouldn't each
cloud smack into the still air and be stopped immediately? In an aerial
view, the smoke should have looked like a trail of breadcrumbs, but it
looked more like a flight of geese. I've repeated the experiment many
times, always with the same result.
ANSWER:
If you drop a bomb
from an airplane, does it stop immediately (its forward motion) when it
hits the still air? No, in fact it will approximately continue on with
approximately the same forward speed it had when you dropped it and
eventually hit the ground directly under you. In the real world, there
is some air resistance and so the bomb will slow slightly and eventually
hit the ground somewhere behind your position. This is evidently what is
happening with your smoke. Suppose that you blow a smokering forward in
a room with still air. It moves forward with a pretty constant speed and
eventually slows down.
QUESTION:
I was in Physics class and we
were discussing half-life. My teacher said that if I keep taking half of
something away, the original piece will never be zero, or will never
disappear. I remembered a problem I heard. If a man shoots an arrow at a
wall, will it ever reach the wall? Because first it has to reach the
half-way mark, then half of the rest of the way, then half of that, and
so on. So theoretically, the arrow won't reach the wall. I know in
reality it will, but how else would you explain this question?
ANSWER:
The notion of half life is a statistical one. That is, the
rate of change of the decaying particles is proportional to the number
of particles; so if you find that a sample of 1,000,000 particles decay
at the rate of 1000 per hour, then 2,000,000 particles will decay at the
rate of 2000 per hour. Then half life is a useful concept. But when the
number of particles gets small, this proportionality is no longer true,
so half life is no longer a useful concept.
QUESTION:
what would
be when an object is obliged to do a work that is greater than its
energy? for example assuming that there is an object at the top of an
inclined plane an it has only a potential energy of mgh. And it is
released to go to the base of the plane but the work must done by the
friction is greater then mgh for instant 2mgh. Also the friction force
is smaller than the component of weight, mgsin&. It must go to bottom
because of gravity but it has not enough energy to go.What would be???
ANSWER:
You are apparently assuming it starts at rest. Then if
friction is equal to mgsinq, it will not go at all. If friction is
smaller, the object will accelerate down the incline because of the
unbalanced force down the incline. However, if it starts in motion and
friction is greater than mgsinq, it will slow down until it stops, that
is until the net work done by the friction and gravity takes away the
kinetic energy.
QUESTION:
So we are teaching kids about the
movement of the earth around the sun. Is it the sun's gravity that keeps
the earth in orbit? What gave it its initial energy to move around the
sun?
ANSWER:
Yes, it is the gravitational attraction force which
the sun exerts on the earth which is responsible for the earth's orbital
motion. In nature, whenever there is a motion of a particle in a circle,
there must be a force which points toward the center of the circle. The
simplest everyday example is a ball tied to a string and moving in a
circle (imagine a tetherball); the string pulls on the ball (the force)
and the result is its circular motion. If you cut the string, the
circular motion ceases and the ball flies off in a straight line.
Depending on the level of understanding of your students, you might want
to talk about Newton's second law: the result of a force is an
acceleration. Then you can talk about how something which moves in a
circle is accelerating even though its speed stays the same.
Acceleration is the change of velocity and velocity can change either by
speeding up or slowing down or by changing direction.
Regarding your
second question, the earth was not created as it is with some particular
orbit but accumulated over billions of years. The current understanding
of planet formation is that, when a star is originally "born", most of
the mass coalesces as the star because gravity pulls it together; but,
because the cloud from which it formed has a little bit of spin to it,
there is a disk of residual dust and rocks going around the star. These
gradually, through collisions and sticking and later gravitational
forces holding bigger pieces together, accumulate to form the planets,
so the planets got their energy from the energy originating in the
motion of the cloud of matter from which system was formed.
QUESTION:
what would be when an object is obliged to do a work that
is greater than its energy? for example assuming that there is an object
at the top of an inclined plane an it has only a potential energy of
mgh. And it is released to go to the base of the plane but the work must
done by the friction is greater then mgh for instant 2mgh. Also the
friction force is smaller than the component of weight, mgsin&. It must
go to bottom because of gravity but it has not enough energy to go.What
would be???
ANSWER:
Absolute potential energy has no meaning;
only changes in energy are meaningful. If we say that the final energy
is equal to the initial energy plus the amount of energy added by
friction (which is, of course, negative since friction takes energy away
from the object), then Efinal=Einitial+Wfriction. If the object is
initially at rest at y=h, then this equation becomes
mv2/2=mg(h-y)-fy/sinq
QUESTION:
Hello-I am an AP physics
teacher in Michigan and neither I nor my students can figure out the
answer to the following puzzle. Tetherball is a game in which a ball is
tied to a pole and two opposing players try to hit the ball so the rope
wraps all the way around the pole. To eliminate the effects of gravity,
the same game can be modeled with a hockey puck on a frictionless plane
tied to a pole with a string. Here's the puzzle: According to
conservation of angular momentum, as the string wraps and the radius
(i.e. length of the string) decreases, the angular velocity of the puck
increases. Because omega=v/r, it can be shown that V
final=(Rinitial/Rfinal)V initial, hence the linear velocity also
increases as the radius decreases. What is doing the work to cause this
increase in KE? In the common textbook problem, a person or other
"energy source" pulls the string inward, hence the person does the work,
the energy coming from the food they ate. But when the rope does the
pulling due to its wrapping around the pole, I can't find the source of
the energy which does the work that must be done to increase the speed.
All of the AP physics teachers I have asked are stumped.
ANSWER:
This is a classic introductory physics problem. Where you have gone
wrong in your analysis is to assume that the angular momentum is
conserved. The condition for angular momentum conservation is that there
be no external torques on the body, in this case the ball. The only
force (ignoring gravity) on the ball is the tension in the string. Now,
since the string does not go through the axis about which you are
computing angular momentum, you can see in the figure to the right that
the tension (labelled F) has a component which is perpendicular to the
line from the center of the pole to the ball, so it exerts a torque on
the ball, so angular momentum is not conserved. Furthermore, the
velocity of the ball (labelled v) is always perpendicular to the string
and therefore F does no work; if there are no external forces doing
work, then the energy is conserved so the kinetic energy does not
change, so the speed of the ball actually remains constant in the
tetherball problem.
QUESTION:
What is known about time travel?
ANSWER:
It is possible to travel into the future using time
dilation, a well-known result of special relativity. This is what is
known as the twin paradox (not really a paradox at all). Basically you
travel to a point far away and back at a very large speed and when you
return more time has passed on earth than for you so you have traveled
forward in time. As far as we know, it is not possible to travel
backwards in time. Read more about the twin paradox here.
QUESTION:
If a plane is traveling at the speeed of light and someone is inside the
plane at the back tail end part and they run to the front of the plane,
would they be traveling faster than the speed of light?
ANSWER:
Well, for starters, it is certainly not possible to travel with the
speed of light because it would take an infinite amount of energy to get
your plane going that fast. But suppose that went with a speed of about
99.999%, for all intents and purposes the same as the speed of light for
your question. If you ran to the front of the plane with a speed of say
99% the speed of light, your speed as seen by somebody on the ground
would be about 99.5% the speed of light. This is fundamental result from
the theory of special relativity—nothing can go faster than the speed of
light and anything with mass must have a speed less than the speed of
light.
QUESTION:
My question is this. Suppose that in the far
future mankind has found the means to travel with the speed of light. If
we manage to send a spaceship 1.000 light years away, equipped with a
extremely powerfull telescope that will be capable of looking directly
to the surface of earth from that distance, will it be looking earth as
it was 1000 years ago or more ( if the distance is greater )? For
instance will it be capable of taking ... aerial photographs of ancient
Rome etc?
ANSWER:
Well, for starters, it is certainly not
possible to travel with the speed of light because it would take an
infinite amount of energy to get your spaceship going that fast. But
suppose that went with a speed of about 99.999%, for all intents and
purposes the same as the speed of light for your question. Then you
would arrive at about the same time as light being emitted from earth at
the time that you left. So if you trained your super telescope back on
earth, you would see things progressing starting from shortly after you
left.
QUESTION:
Is it possible to speak about a "speed of
darkness" or that is only the opposite of the speed of light since
darkness is the absence of travelling photons?
ANSWER:
"Darkness"
is not something physical and so it is rather pointless to talk about
its speed. If you have a flash of light, there is a spherical shell of
light expanding out from the source with the speed of light, so the back
side of the flash is the edge of advancing darkness behind it, so I
guess you could say that the darkness is increasing with the speed of
light.
QUESTION:
I don't know why this would be of any use but,
If you mounted two conductive parallel plates of large magnitude to the
top of a lightning rod with the top plate suspended by an insulator and
lightning struck the top plate, would that be like charging a giant
capacitor?
ANSWER:
Sure, assuming that equal and opposite charge
could be acquired from the ground for the lower plate. However, it would
likely not happen since lightening "selects" a path where the charge can
find a route to ground.
QUESTION:
If you set off a nuclear
weapon in a black hole what would happen? I thought nothing because the
particles would not be able to move around because of the super stong
gravatational pull.
ANSWER:
You could not get a nuclear weapon
into a black hole in tact.
QUESTION:
i was once concidering the
effect of propelling an object backward off a moving vehicle with the
exact velocity that you are travelling. From my point of view the object
is moving away from me, but to an observer standing at the side of the
road at the instant i throw the object it merely drops to the ground.
This made me wonder if it is possible for light to behaive in the
similar manner. In this hypothetical situation an object must be
travelling the speed of light. Would the light from the object
travelling in the opposite direction of travel merely stand still in
space becoming "dead light" or would it accelaterate to it's regular
pace. In this situation we would also have to assume that the object is
generating it's own light since light itself would not be able to
reflect off it due to it's speed.
ANSWER:
It seems like I answer
this question (in various forms) at least weekly! There are two problems
with your hypothesis, both violations of the theory of special
relativity. First, no material object may have a speed equal to or
greather than the speed of light; the reason, simply, is that to
accelerate it to the speed of light you would have to supply an infinite
amount of energy, obviously not available. Second, one of the basic
postulates of the theory of theory of special relativity is that the
speed of light in a vacuum is the same for all observers. Thus, even if
your object were moving with 99.99% the speed of light (which is
possible), an observer at the roadside would see the light from its back
end moving with the speed of light, not 0.01% the speed of light. The
theory of special relativity is completely verified experimentally and
no serious scientist doubts its correctness.
QUESTION:
what
would happen if a small hole was drilled right through Earth, that is
from one side to another going through the Earth's core, and I so happen
to drop an object into that hole, would the object fall right through,
fall towards the middle and stay there, or result in a ping pong effect?
(Given that the posibillty of creating such a hole is possible, without
a catastrophic event happening)
ANSWER:
This is a classic
introductory physics problem. The object will speed up until it gets to
the center and slow down until it gets to the hole opening at the other
side, will then start speeding up back toward the center, etc. If the
earth is modeled as having uniform mass density (which is only roughly
accurate), the motion of the object will be what we call simple harmonic
motion, that is it will behave exactly as if it were attached to a giant
spring.
QUESTION:
Is it possible to contruct a machine that
repels gravity?
ANSWER:
I don't really know what you mean by
"repels gravity". I suspect you are interested in an "antigravity"
machine. The answer is yes, there are lots of antigravity machines. One
is an airplane which wants to fall to the ground. Another is a tabletop
which keeps a book on it from falling to the ground. I am obviously
being a little facetious here. What would be neat is to have something
which is repelled instead of being attracted by a gravitational field.
For this to happen, there would have to be another kind of mass (just
like in electrostatics we have two kinds of electric charges and so we
can have both attractive and repulsive forces). As far as we know, there
is only one kind of gravitational mass.
QUESTION:
what happens
when parallel rays are incident on a plane mirror?
ANSWER:
The
reflected rays are also parallel.
QUESTION:
The other day I was
watching a child play with one of those funfair baloons, filled with
(what i think is) hellium. Often children let go these ballons, and they
just keep on rising and rising... My question is: how high will such a
ballon rise, assuming minimal wind (i.e. if the ballon rose approx.
vertically)? What if the ballon had hidrogen instead of hellium? Is it
different?
ANSWER:
The reason the balloon rises is the same
reason wood floats. When an object is in a fluid (like air or water) it
experiences an upward force (called the buoyant force) equal in
magnitude to the weight of the fluid which it displaces; this is called
Archimedes' principle. So the balloon has two forces on it, its own
weight down and the buoyant force up. If the weight of the air displaced
by the balloon is greater than the weight of the balloon, there is a net
force pushing up which will push the baloon up. This will be the case if
the balloon is filled with helium but not if it is filled with water,
for example. Now, the air in our atmosphere has, as you probably know,
the property that it gets less and less dense as you go higher and
higher; for example, it is quite hard to get enough air on top of Mt.
Everest and airplanes which fly at more that a few thousand feet must be
pressurized. For this reason, the buoyant force gets smaller and smaller
as the balloon rises until, eventually, it is the same as the balloon's
weight and it will stop rising. I have ignored, in my explanation, the
fact that the balloon will get larger as it goes higher because the
pressure of the gas inside stays about the same while the pressure of
the air on the outside gets smaller; I think the important thing to
appreciate is the Archimedes' principle thing. This is the principle
which lets "lighter than air" craft (hot air balloons, blimps, etc.)
fly.
QUESTION:
why can't visible light waves penetrate most
solid walls, yet every frequency below and above visible light can, such
as radio waves, gamma, micro, etc?
ANSWER:
You are incorrect in
stating that "every frequency below and above visible light can"
penetrate. Electromagnetic theory shows that there is a distance called
skin depth at which any electromagnetic wave will decrease to about 1/3
of its amplitude outside the medium. For conductors the skin depth
depends on the wavelength in such a way that long wavelength waves can
penetrate much farther without significant loss of intensity. At the
short wavelength end of the spectrum (gamma rays, for example) the usual
theory breaks down because we have very energetic single photons
interacting with the atoms in the material and doing such things as
losing energy by ionizing atoms their its paths; here, the more
energetic (i.e. shorter wavelength) the photon, the farther it will go
before using up all its energy.
QUESTION:
I was taught in school
that the speed of light is the speed limit of the Universe. Nothing can
go faster than light. In E=MC2, the speed of light is squared. If
nothing can go faster than C, why does the the equation get square C.
Isn't C2 faster than C?
ANSWER:
But, this equation does not mean
that something is going with a speed c2. In fact, going with a speed c2
does not have any meaning since speed squared would be measured in, for
example, miles2/hour2 which are not the units of a speed. Just because c
(3x108 m/s) is the fastest possible speed does not mean that c is the
biggest possible number. There are, for example, many more than 3x108
stars in the universe.
To see questions and answers from longer ago,
link here.