QUESTION:
When they talk about entangled
particles, what types of particles
can get entangled? And If 1 of 2
entangled particles experienced time
dilation, (Through trips around a
particle accelerator) with the
affect of time dilation split the
difference between the 2 particles
and 1 is having the affect of
"observer" speed applied while the
other has "slower" speed applied?
Would there be any measurable
affect? Would "Spooky action" occur
at time-since entanglement? (ie, If
"Normal" particle was impacted x
seconds after entanglement and time
dilation, would the affect apply in
the observer time "instant" or delay
until "Slow" particle caught up to x
seconds since entanglement and time
dilation)
ANSWER:
The easiest way to think about
entangled particles is that they are
both parts of the same system. The
particle states are correlated such
that the system all changes
together. That, of course, is
Einstein's "spooky action at a
distance". So rather than thinking
of the second particle changing its
state when the other is measured
because it somehow detects this
change, it is simply doing what it
is required to do because the two
particles are really one system.
Because the changes are apparently
instantaneously happening, there is
no need to worry about the clocks of
either of them. This is why they are
called entangled—they are really a
single quantum system. Indeed, two
entangled particles are entangled
regardless of their positions and
frames of reference. An observer in
any frame of reference will see the
change of quantum states to be
instantaneous and if that is true,
clocks are irrelevant—instaneous is
instantaneous.
QUESTION:
Context: you're an astronaut in
geostationary orbit around the
earth. How much smaller in % would
the earth look if there was no
gravitational lensing? Or in other
words how much bigger does
gravitational lensing make the earth
appear (if at all)?
ANSWER:
The equation to calculate the
angle of deflection θ is
θ =4GM /(rc 2 ).
I get θ =(1.7x10-9 )°.
Something tells me that you will
have no chance of observing a
nanodegree! Don't even bother
messing with the percentage.
QUESTION:
I am a retired UMASS Medical School
associate professor in molecular
neuroscience who has a longtime
interest in the quantum realm but
unfortunately never pursued it when
getting my chemistry degree from
UCSD. I have a question that relates
to the quantum nature of electron
energy levels in atoms. Electron
energy levels in atoms relate to the
nuclear structure of the atom
itself. Is it possible to know
anything about these orbitals in the
absence of electrons? In other
words, when electrons are stripped
from an atom, do these orbitals
remain of the same nature in the
absence of electrons, or is it only
possible to truly speak of these
energy levels when an electron is
present or nearby; ie, they only
make sense when the interactions
take place between the electron and
the nucleus? Maybe in the absence of
an electron these orbitals exist in
a virtual sense only.
ANSWER:
What matters in quantum
mechanics is what the 'system' is.
Once you have specified the system,
you need to solve Schrödinger's
equation for the system. The wave
function for an oxygen with 5
electrons stripped off is different
than the wave function for an
un-ionized oxygen atom; therefore,
the answer to your question is no,
changing what the 'system' is will
change what the wave function is.
Along these same lines, the energy
spectrum of the O5+ will
be different than un-ionized oxygen.
QUESTION:
So, we can determine the earth's
movement in relation to other
astronomical objects, but we have no
idea of our absolute movement,
correct? The earth is spinning and
revolving around the sun which is
revolving around a galaxy that is
expanding from other galaxies in the
universe. But wouldn't we need to
know our velocity in absolute terms
to know our relative time? For
arguments sake, the universe could
be spinning or moving at a million
miles/hr. Our time is dependent on
our velocity. If light speed is a
'constant'… doesn't velocity depend
on time (m/s) whereas time depends
on velocity? Wouldn't that be
circular logic?
ANSWER:
The time you are interested in
is the time in your frame of
reference. In your example of the
"universe moving at a million mph",
it has no relevance to whether the
laws of physics are true in your
frame. (Actually making that
statement is not meaningful because
what is the whole universe moving
relative to?) You seem to think that
in your moving frame something would
change if you accelerated to a
higher speed. Once you got to that
speed and turned off your engines,
there would be no experiment which
you could perform to detect that
change. There is no such thing as
"your absolute velocity". All times
in frames relative to yours would
depend on their velocities relative
to you; your time would, for you
just tick away like it always has. I
guess you have not studied special
relativity which reveals to us that
there is no such thing as "absolute
time", there is no god somewhere
with the master clock which everyone
compares to.
QUESTION:
If a system is spinning at 2% of the
speed of light or more, it starts
leaking energy in the form of
photons. Could you remind me what
that is called?
ANSWER:
I don't know about your 2%
number but I do know that an
accelerating charge radiates
photons; this is called
bremsstrahlung .
QUESTION:
I have made one of these for use in
the kitchen for measuring small
quantities but I cant figure out the
scale graduations because its
non-linear. If I can get the formula
I can use a spreadsheet to display
the scale graduations and then do a
screenprint. The beam I used was 3mm
steel rod. I can send a photo of the
device if that would be useful. This
type of scale is useful because its
very cheap and easy to construct
(and no batteries needed ! )
ANSWER:
I have redrawn the picture you
sent, replacing your thread by a
fulcrum which does not matter. My
notation:
being
measured.
g
is the acceleration due to
gravity.
D
is the length or the beam.
f
is the fraction of the
length of the beam on the left
of the fulcrum.
μ
is the mass density of the beam,
mass per unit length, so μD
is the mass of the beam.
θ is the
angle which the beam makes with
the horizontal.
Let's sum all
torques about the fulcrum,
MgfD cosθ +(μgfD 2 /2)cosθ -(μg (1-f )D 2 /2)cosθ =0.
This is a
scale, so we want M as a
function of θ. Solving the
above equation for M I find
M=μD [1-(1/(2f ))].
Note that M is not a
function of the angle, so your scale
will not work. Once you have found
the right f for the given
M , it will be in
equilibrium regardless of the angle.
If you want to learn more about
balances and their designs, there is
an earlier answer to a question
which you might like to
link to.
QUESTION:
I work in the medical imaging field
and once had demonstrated to me how
much resistance to mechanical motion
eddy currents can have. The MRI
field service engineer placed a
non-ferrous quarter in the bore of
the MRI. In one orientation it fell
over normally. Rotated 90 degrees if
fell as if moving through molasses.
He told me it was due to eddy
currents. I also play electric
guitar. Electric guitar strings are
both conductive and ferrous
materials. I tested that with my Ohm
meter and a magnet to double verity.
The electric guitar has pickups to
pick up the vibrations of the
strings and amplify them. I do not
understand how they work. The common
explanation is it's due to the
magnetic force pulling the strings
down, changing the moving strings
path in some way. I am also
wondering if eddy currents may be
playing a role. Granted the pole
pieces are not particularly strong,
especially compared to an MRI.
Question 1) I assume eddy currents
occur in ferrous and non-ferrous
materials both so long as they are
conductive, correct or incorrect?
Question 2) Is it feasible that
eddy currents in the strings resist
motion in combination with a
magnetic pull even though the
magnetic strength is nowhere near
1T?
ANSWER:
I edited your question to take
out a lot of extraneous rambling.
You clearly do not understand how
the pickup works, but you are in
good company—when I was googling I
found that easily half the
explanations about the physics were
wrong or so vague as to provide no
explanation. To understand what is
going on, you need to understand
magnetic induction of electric
current, first discovered by Michael
Faraday. In a nutshell, if you have
a changing magnetic field you will
induce electric currents in nearby
conductors; also, because of
relativity, if the nearby conductors
are moving and the magnetic field is
constant, you will still find that
currents are induced in the
conductor (as what is happening with
your quarter in the MRI). Of course,
if you have currents they will have
their own magnetic fields; this
plays an important role in the
guitar pickup too. So let's look at
what is going on:
There is a magnet for each
string and each magnet is a
small bar magnet;
there
is a coil of wire (hundreds
or thousands of turns) and the
two ends of the wire will be
accesible to be the output of
the coil to amplify.
of
course, there is a string, which
is which is fabricated from a
conducting metal;
if the
string is not vibrating there
are no currents anywhere because
the magnetic field is static,
not changing.
now the
string is plucked so the string
vibrates so it is moving through
the unmoving field of its
magnet;
because
the string is a conductor there
will be an electric current
induced in it and it will be
varying with the same frequency
as the vibration;
now we
know that electric currents give
rise to magnetic fields so the
vibrating string will have its
own magnetic field;
this
induced field will be seen by
the coil;
since the
current will be constantly
changing, its magnetic field
will be changing;
this
changing field will now be
passing through the coil and
there will therefore be an
induced current, same frequency
as the string;
the
current will be passed through a
load causing a voltage which can
be amplified electronically and
sent to the speakers.
QUESTION:
I’m not well schooled and I’m well
up in age, but I’ve been wondering
if the Earth rotates at 1000 mph and
a passenger airplane can only fly at
a top speed of 500 mph. How can it
fly from California to New York
without the Earth staying ahead of
it is it gravity a magnetic pull ?
ANSWER:
The atmosphere moves, for the
most part with the rotating earth.
The airplane flies relative to the
air, so it's like paddling a canoe
downstream in a river; if you don't
paddle, you move along with the
river but if you do paddle you move
faster than the water. Also, the air
does move at different speeds, it's
not just a static blanket of air;
winds blow depending on the
conditions of the air (weather). The
most permanent high-speed (more than
100 mph) winds are called the jet
stream. Flying across North America
or to/from Europe to North America,
because jet planes fly at the
altitudes (30,000-40,000 feet) where
the jet stream is, the flying time
is almost always shorter going W to
E than E to W because the
jet stream mainly goes to the
east.
QUESTION:
I was wondering what would happen if
2 10g ball bearings travelling close
to the speed of light collide in the
LHC. Obviously I'm assuming a lot
here. Such as The LHC wouldn't break
by putting non-particles in there.
The structural integrity of the ball
bearings would remain stable for the
duration of the experiment The balls
could even reach that speed in the
first place There was enough energy
to do this. I think it would be
fascinating but I'm not a physicist.
I hope I'm not wasting your time.
ANSWER:
Most people, like you, have no
concept about how huge the energy of
macroscopic objects going close to
light speed are. I have answered
questions like this before which
might interest you (See
faq.html#faq game scifi guns ).
Apart from the vacuum inside the
LHC, there is no reason for it to be
in this question. Let's just say
that two bearings in a vacuum, each
of mass m =10-2
kg and moving with a speed of 90%
the speed of light. Each has energy
E =[10-2 /√(1-0.92 )](3x108 )2 =2x1015
J. The Nagasaki bomb had a total
energy of about 1014 J,
so each of these bearings would have
about 20 WWII era atomic bombs. If
you took 2x1015 J and
delivered it over the period of one
day, it would be equivalent to a
power of P=E /t =2x1015 /(3600x24)=23x109
W=23 GigaWatts; that's about 6 times
larger than the biggest power
station in the US. You may assume
that the "structural integrity of
the ball bearings would remain
stable for the duration of the
experiment" but there is no way that
could possibly happen if there is
this much energy. We are talking
about 4x1015 Joules of
energy which is the energy of a
typical H bomb.
QUESTION:
I'm trying to measure a slit width
by passing a laser through it of
known wavelength and distance the
slit is from screen. Unfortunately,
that requires close to absolute
darkness as the resultant beam,
after passing through the slit, is
like a super fine thread and very
hard to measure. My task is to
determine how fine the adjustable
slit can go down to, in order to
maximize the resolution of a home
brew spectrophotometer . My problem
is that I need to get my eyes "dark
adapted" to see this very fine line
of light on my white graph screen.
Unfortunately, the laser is very
bright, which messes up my dark
adaptation and makes the projected
laser image very hard to see and all
the more so, measure on the screen.
ANSWER:
So, by best resolution you
probably mean the narrowest width
possible. And, it seems that you are
having trouble even seeing the light
on the screen because the light line
is so narrow that it has
insufficient light to be seen well.
You are barking up the wrong tree, I
believe. There are actually two
things you need to understand:
T
he
width for geometric optics. If
the slit is much bigger than the
wavelength of the light, the
image is simply identical to the
slit as shown in the figure. The
angle can be written as θ1 =s /R =d / R
Eventually the slit will become
comparable to the wavelength.
Significant broadening of the
light passing through the slit
will occur due to diffraction.
The single slit diffraction
pattern looks like the next
figure: Now the width of the
image, s, will be the distance
between the two zeros of
intensity of the central peak;
this can be shown to be θ2 =λ /d .
where λ is the wavelength of the
light. Finally I show a graph of
θ2 (red), θ1
(black), and their sum (blue).
The narrowest possible image can
be shown, by finding the minimum
of the blue curve, to be θbest =√(λR ).
If you are
interested you can read a beautiful
example of an application of all
this, the eye of a bee, in Section
36-4 of the
Feynman Lectures . This will also
give you more detail filling in my
"it can be shown"s.
I suspect
that you will not be able, with your
apparatus, to get out of the
geometrical optics region. But from
your question I suspect that you
will need to make a compromise
because you probably don't have
enough intensity to do your
measurements.
QUESTION:
How much energy would it take to
launch a man 3,000 kilometers away
in an instant? And let's say for
this hypothetical, the man is
somehow durable enough to withstand
this.
ANSWER:
You don't define what an
"instant" is. It usually means "in
zero time" as in instantly. The
answer, then, is infinite energy. It
is physically impossible for
anything to move through some
distance instantly.
QUESTION:
Does the speed of light change when
it is passed through a prism and is
broken up into the various color
bands? Do the different colors of
light, in the light spectrum, travel
at different speed when project into
an environment void of light? If,
say, red light is projected into a
completely red light environment, is
the speed of light measurable?
ANSWER:
The speed of light in a
vacuum has the same regardless
of what its wavelength is. Most
experiments would measure the speed
in air, not a vacuum, but air has an
index of refraction extremely close
to 1; therefore the answer to your
first two questions is, for all
intents and purposes, no. Your third
question has no meaning
("…completely red light
environment…")
QUESTION:
I know the electric potential energy
is negative for opposite charges.
But initially when we move the
charges (consider bar magnets) from
infinity to say 20cm apart the force
is applied by my hand since they
aren't in each others electric
fields. The force is in the same
direction as displacement and work
is positive. I get that EP becomes
negative when they are in the
influence of each others fields but
why is EP positive intially?
ANSWER:
"…consider bar magnets…"? Bar
magnets are not electric charges* .
You need to consider two electric
charges, q and Q.
Imagine Q to be held fixed.
The work done to move q
from r 0 to r
is W=kqQ [(1/r 0 )-(1/r )];
if r 0 =∞,
W=-kqQ /r. The
potential energy U is
defined as U (r )=-W =kqQ /r.
Note that I have chosen U (r 0 =∞)=0.
So, if q and Q
have the same sign, U (r )>0
for all r and if q
and Q have the different
signs, U (r )<0 for
all r . I have left off all
the steps leading to W =…
and U=-W ; you can find
these in any physics text or on the
web, e.g. this
link .
*Because
magnetic forces are velocity
-dependent,
they are not conservative forces so
you cannot introduce a potential
energy for them.
QUESTION:
I'm currently in the process of
Worldbuilding my own character's
story. [I have no idea what this
means!] If the universe, instead of
a vacuum, were an infinite "block"
of matter, expanding forever in
every direction, how would gravity
behave inside a spherical hole (at
the theoretical center of this
infinite matter) within this
infinite block of matter? So far, I
have only ever found mathematical
formulas to determine gravity inside
an empty sphere but I am unsure if
that behaves different if there is a
vacuum outside the sphere (which, in
my case, there is not). [This
question was originally way too long
and I have edited it because the
answer is simple.]
ANSWER:
I assume that the mass of your
block is uniform and that it has
spherical symmetry; to assure
spherical symmetry, the block should
be a sphere. Physicists like to
avoid infinities so just make it
extremely large (like billions of
light years). The gravitational
field inside a thin uniform
spherical shell is zero everywhere.
This was proven by Newton, in fact
it is supposed that this question
was the main reason why he invented
calculus. There are several
consequences of what is called the
shell problem. First, the field
inside a thin spherical shell is
zero. Second, a thin spherical shell
will give rise to a field outside
which is the same as if all the mass
of the shell outside were
concentrated at the center of the
hole. Third, the shell need not be
thin since you can imagine adding
many thin shells like an onion
making a thicker and thicker shell,
each having the shell theorem
applied to it. The gravitational
force in the matter will linearly
increase the farther you get from
the center (another reason for not
being infinite). If it is expanding,
is mass being created somehow? Or,
if mass is conserved, it must be
getting less dense. And if it is
getting less dense, it must be
compressable which means that it is
getting more compressed at larger
distances than closer to the hole;
this would still result in zero
field inside the hole but the field
in the matter would not increase
linearly anymore. If you added any
more holes, all bets are off because
that would destroy spherical
symmetry; however, if the holes were
much farther apart than their sizes
it would be an excellent
approximation that the fields would
be zero.
QUESTION:
When I try to calculate the power
draw from the recirculator pump on
my furnace, I get two different
answers.
When I multiply the volts x
Amps, I get 0.71 Amps
115Vx0.71Amps=81.7 W=0.109 hp.
T
he
hp rating of the pump is 0.04
hp=29.8 W.
Why the discrepancy? Do I have
to use the RMS value of the AC line
voltage to get the right value?
ANSWER:
I actually had no idea because I
did not know how water pumps are
rated. They are not rated by power
but rather by head (H) times flow
(F); on a
site I found the statement is
made that "Unlike motors, pumps
are rated by head and flow, not by
power. There’s no such thing as a
50-horsepower pump ". The
relation between H, F, and
P is (P=H xF )/e
where e is the efficiency
of the pump. I believe that where
you went wrong is to compare the
input power to the output power
which will not be equal unless the
pump is 100% efficient which it
never will be. If I understand all
your numbers, the pump efficiency
will be e =1-(29.8/81.7)=63.5%.
The site I found most helpful is
here .
QUESTION:
Why do the moons of other planets
have names, while the name of our
moon is simply moon.
ANSWER:
This can be confusing! The word
moon means any natural
satellite orbiting a planet; here
natural means it is not man-made.
The space station is a satellite but
not a moon. "The Moon" refers only
to the moon which orbits earth. Note
the capitalization of the Moon which
sets it apart from all other moons;
the Moon is a moon! Astronomers
often refer to the Moon as Luna, the
Latin word for Moon.
Io ,
Europa ,
Ganymede , and
Callisto are moons of Jupiter
and were the first moons of another
planet to be discovered (by Galileo
in 1610). Hundreds of exoplanets
(planets outside our solar system)
have been observed but no undisputed
evidence for exomoons has been
found.
QUESTION:
I have a masters degree in
Electrical Engineering. We are
mainly schooled in classical
electrodynamics (Maxwell and Hertz).
The more I read about quantum
mechanics, the more I think that
electromagnetic waves (as described
by Maxwell) really don’t exist and
is purely a mathematical contrivance
(although Maxwell’s equations do
great job predicting what happens at
a macro level). I am aware that
photons contain discrete amounts of
energy. If we look at an antenna and
why the electrons start moving back
and forth and produce a small
voltage when radio waves hit it is
because the waves have oscillating
magnetic and electrical fields.
Because electrons have electric and
magnetic moments, these fields
“push” the electrons around (pretty
classical description of a force).
The quantum mechanics description of
what is happening seems very
different. My crude interpretation
seems to be that a quantum particle
called a photon binds to an electron
and gives information to the
electron (hey, Mr. Electron, that
transmitter says you move that way).
Some of the literature seems to
imply that energy is just
information and the electrons move
because that’s what they were told
to do and that’s what they do.
ANSWER:
Classical Electricity and
Magnetism (E&M) is what
mathematicians call a classical
field theory. It is probably the
most fully understood theory in all
of physics. It is beautifully
expressed and, in its most complete
form, fits in perfectly with special
relativity (which most physicists
consider to be a classical theory
replacing Newtonian mechanics). But
in the early years of the 20th
century a couple of experiments
seemed to not be in agreement with
E&M. First was the photoelectric
effect and the other is Compton
scattering. I will leave it to you
to learn about these results in
detail if you already haven't. In a
nutshell, they provided evidence for
photons. The photoelectric effect:
Shining ultraviolet light on the
surface of a metal results in
ejection of electrons which have
energies consistent with the
existence of photons which have
given all their energy to
an electron in the metal. Compton
effect: Photons can also be observed
to interact with with an electron by
simply scattering from it, thereby
losing a some of its
energy, and that is also observed. I
don't know where you got "…a photon
binds to an electron and gives
information to the electron…", but
it is not correct on any level.
Photons interact with electrons.
Finding the constituents of a field
which are the smallest possible
amount of energy that can still be
identified as being in that field is
indicative that the classical field
can be "quantized", expanding it to
a quantum field. This was not
achieved mathematically until the
late 40s, early 50s. In a quantized
field the quanta (photons in your
case) of the field may be thought of
as the "messengers" of the field,
the way that the field operates
mechanically by communicating forces
between electric charges. With
quantization of the field, E&M is
physics' most well-understood and
complete theory. Just because
quantized fields indicate that you
understand E&M more deeply does not
mean that classical E&M should now
be discarded. It is still
appropriate to use classical physics
to describe classical problems. If
you want to describe antennae, you
would be foolish to use photons to
do so. Your conjecture "…that
electromagnetic waves …really don’t
exist…" is wrong and I hope that I
have convinced you that the
inclusion of photons is simply the
completion of the theory of
electromagnetism.
QUESTION:
Since the the 1970’s air
conditioning has become standard on
all new vehicles and in all
buildings. In my car the AC is set
on auto and my windows are closed so
anytime the temp is warm the AC
cools the interior. I know for every
action there is an equal opposite
reaction. Cool air inside equals hot
air expelled outside. So are all
these air conditioners all over the
world contributing to global warming
by emitting heat into the
atmosphere?
ANSWER:
What an air conditioner does
is move heat from inside to outside.
There has been no net change in the
overall energy of the atmosphere.
(Heat is the flow of a certain
amount of energy from one place to
another. However, this doesn't just
happen, it must be made to happen.
You use electrical energy to cause
this zero net change in energy, to
move that energy. That energy is
likely to come from an electrical
power plant pouring tons of carbon
into the atmosphere.
QUESTION:
how many H2O molecules does
it take to make water ... with the
characteristics of water, i.e.,
solvent, liquid, etc.?
ANSWER:
One of the main concerns of
nanotechnology is to answer this
question. Of course, there is no
clear answer since there will be a
continuous transition to the bulk
value of each property being
measured as more molecules are
added. A very important
consideration is the the ratio of
the surface area of the cluster to
the volume; this is because the
molecules on the surface are
interacting with fewer neighbors
than those inside are.
QUESTION:
I am NOT a scientist, just a
curious layman. I’m 74 years old;
this isn't homework. On the question
of singularities— doesn't quantum
theory pretty much disprove them?
I'm guessing that if energy (and
pretty much everything) can be
considered a wave function, then
doesn't any wave have to have some
amount of volume in order to exist?
Or is this question just
highlighting the well known problem
with the existence of singularities.
ANSWER:
Nearly all physicists, like me, are
uncomfortable by any discontinuity.
Black holes as described by general
relativity (GR) are singularities
but that just indicates that GR,
while a beautiful and successful
theory in describing gravity in
general, isn't totally right because
there aren't really any infinities
in nature. You are on the right
track by thinking of quantum
mechanics because the uncertainty
principle basically implies the
impossibility of a point particle
(infinite density) at rest; on the
other hand, there is no guarantee
that the laws of physics are the
same "inside" a black hole, in fact
very likely not. Another example of
an infinity in an otherwise
successful theory in condensed
matter physics; when phase changes
of materials occur (e.g.
freezing of water) in certain
observable properties or their
slopes may instaneously change, an
artifact of the theory.
QUESTION:
I am a freshman in high
school and in science class we were
learning about planets, moons, and
stars, and their sizes compared to
the size of earth. I was wondering
how we can determine the sizes of
different planets, moons, and stars
with them all being at varying
distances away and all looking
relatively the same size in the sky?
ANSWER:
They only appear to be the same size
in the sky because your naked eye
sees all distant objects as more or
less point light sources. To be able
to estimate their sizes you need a
telescope to magnify what you
see.
So, suppose that you have a
telescope which allows you see
Jupiter, for example. Now, that
telescope has nice crosshairs in it
so you can first aim it at one side
and then rotate it to the opposite
side. You measure the angle (A
in the figure). Now, the angle is
related to the diameter D
and the distance to Jupiter R
by A=D /R . If you
are a freshman you may not be
familiar with the units A
has in this equation. The units are
called radians and there are 2π
radians (π =3.1416 as you
probably know) in a whole circle
just as there are 360 degrees in a
whole circle. So let's see what
A is for Jupiter: D =1.428x108
meters=88,732 miles and R =7.14x1011
meters=444 million miles. So now we
can calculate the angle, A =1.428x108 /7.14x1011 =0.0002
radians=0.0115 degrees. This is a
really tiny angle and you can
understand how you would see it as
only a dot with your naked eye. We
say that Jupiter subtends and angle
from earth of about 0.0115 degrees.
Of course,
this gets really hard to do for
smaller objects like moons or very
distant objects. Today, these are
determined by getting up close to
those objects with probes which we
have sent to space for the past 70
or so years. But once you get closer
you still use the subtended angle
method.
Stars are
harder still to measure. If the star
is big enough and/or close enough,
you can still do the subtended angle
direct measurement method; this is
done with a really powerful
telescope where you can take a photo
and then just measure the diameter
of the image. There are other
methods. Like if you find a binary
star pair (two stars rotating about
each other) you can measure the time
it takes for an eclipse to occur and
calculate the size of the star. If
you can see a planet in orbit around
a star you can infer the time it
takes the planet to cross in front
of the star.
I could go
on, but maybe this is a good place
to stop. Say hello to Ms. Welch from
me!
QUESTION:
In Einstein's book The Theory
of Relativity, I read that gravity
is not a force but rather an
acceleration or curvature of
spacetime that pulls objects toward
regions with high mass or energy
density. If gravity is not a force
but a field curvature, then why are
physicists trying to find a theory
that unites gravity with the other
three forces? After all, if gravity
were a force, black holes wouldn’t
be able to attract massless photons.
Why are we trying to unify something
that is not a force with forces?
ANSWER:
I have answered this question
several times before. I think that
this
earlier answer is the first time
I answered it (just the paragraph
starting with
"…While researching this question…"
is relevant for you). Unfortunately
the link to the essay is no longer
on line, but you can get the gist of
it from my summary. The bottom line
is simply that a mathematical
theory, general relativity, can be
interpreted in more than one way; in
this case, GR could be interpreted
as geometry or as a quantum field
theory.
QUESTION:
I've never realised it before
but the solar system is constantly
moving. I saw an animation that
almost scared me. It's the sun
travelling through space and the
planets following slightly behind
spiraling around it. I found it
amazing. My question is if we’re
constantly moving, are there areas
in space that could be warmer,
cooler or have more radiation in it.
I’m not sure how to explain it.
Almost like an atlantic fish showing
up in the pacific and we wouldn’t be
able to toleratee it basically.
ANSWER:
First of all, whenever you talk
about something moving you must
specify "with respect to what?" I
found the
animation you saw, I think.
[There seem to be several of them.]
The video I watched was very
"pseudoscience". For example, saying
that the usual picture of the solar
system is incorrect is, well, just
incorrect. The usual picture shows
how the solar system looks when
viewed from the framework of the
sun. If you now view from the
framework of, say, the center of the
galaxy, and look at the paths of the
planets, you see those very pretty
helixes; now the narrator waxes
eloquently about the profound
meaning of his "vortexes", calling
what he sees the helical model of
our solar system, as if this were
some meaningful new law of physics.
In fact if you just didn't draw the
paths you would simply see the usual
picture of the solar system moving
past you. Also, since the solar
system is rotating in an orbit
relative to the galaxy center, most
of the stars and other nearby stuff
is also in about that orbit so that
our neighborhood moves with us
keeping our region of space more or
less constant. And space in our
region of the galaxy is more or less
empty on scales much bigger than the
solar system, so don't spend your
time worrying about suddenly being a
"fish out of water" (to use your
metaphor). If you want to see a very
good and scientifically accurate
video about the path of the solar
system throught space, I would
recommend
this PBS video.
QUESTION:
What is the optimal size
(circumference) and weight of a ball
such that it could be thrown faster
than any ball currently thrown by a
human. I'm assuming that using
physics there is a way to determine
the amount of force imparted on the
baseball thrown by Aroldis Chapman,
and then extrapolate that to
optimize a ball size/weight such
that his throw could exceed 105.8
mph with perhaps this optimized
ball. (I have edited this question
to make it more concise and
well-focused, but it doesn't matter
since there is no possible answer.)
ANSWER:
Your question is based on the
assumption that if you know the
force exerted on the ball you can
calculate the speed that the ball
would have. In fact that is false.
Please go to the
this link to see this discussed
in some detail; you will see that
the mass plays an important role in
calculating the speed reached but
the size is irrelevant. One thing
which would make a larger ball
matter would be how awkward it would
be to throw it. Also, the human arm
doesn't apply a constant force over
the distance the ball moves while
the throw is in progress and this
would likely vary.
QUESTION:
How would I calculate for the
μ of kinetic friction with the force
of kinetic friction and the angle on
which a wood slider starts sliding
down an angled wood board.
ANSWER:
Actually you can't. Let me explain
why. If you have an object on the
board and lift the board so it makes
a small angle with the horizontal,
the object remains at rest. Why?
Because static friction is holding
it there. Static friction is what
keeps a heavy box from budging when
you haven't been able to get it
moving. Imagine you have a heavy box
on a level floor: If you push with 5
lb of force it doesn't move because
the static friction is 5 lb in the
other direction; if you push with 10
lb you maybe still woulb be unable
to move it. However, at some point
the friction is just not big enough
stop you and the box starts moving
and you can push it across the room
against the kinetic friction force.
If you have ever done this you know
that the box initially "pops" away
and starts speeding up. You
can infer from this is that the
coefficient of kinetic friction is
smaller than the coefficient of
static friction.
fs ≤μs N,
fk =μk N,
and μk <μs .
In the figure
there are three forces on the block
if it is not slipping: its weight
W , the
static friction coefficient
f s ,
and the normal force N
which the board exerts on the block.
Since it is not slipping we can use
Newton's first law to determine
N=Wy =W cosθ
and f s =Wx =W sinθ.
Now keep slowly increasing the
angle until at some angle θ 0
the block starts sliding,
accelerating down the incline. At
this angle, fs =μs N=μs Wcos θ=W sinθ ,
so μs =tanθ .
So you can measure the coeficient of
static friction this way, but not
the coeficient of kinetic friction.
QUESTION:
I think you can make a
microscope using a regular 3,000X
microscope and two drops of water in
a tube of fluorinated oil.
Fluorinated can be used as a lens.
They can adjusted the density, to be
very near the density of water. You
can search the internet: Can you
make a lens with a drop of water in
fluorinated oil? It says it is
potentially possible. So I think you
could put two sphere drops of water
in a tube of fluorinated oil. Then
you could look into the tube with a
3,000X microscope. And, you could
put a layer of water in the tube,
below the two drop lenses. Each drop
could be 100X. So all together, you
could magnify, 30 million. You could
see viruses while they are alive,
and through them. The big scopes,
don't do both of those.
ANSWER:
I don't know much about microscopes.
But doing a simple search I find
that optical microscopes have
maximum magnification of 500-1500x
but that the usual max is about
1000x because at 1500x the image is
enlarged but reveals no more detail
than at 1000x. It is simple physics
that geometric optics stops working
when the object is the same order of
magnitude as the wavelength of the
light you are using. One rule of
thumb is half the wave length of the
light is the smallest object you can
observe. For example, using 340 nm
light (shortest wavelength visible
light, violet) you could not get a
well-focused image for an object
smaller than about 170 nm and
viruses are typically about 100 nm.
That's the best you can do with an
optical microscope, nothing gained
by adding magnification.
QUESTION:
It is said that acceleration
is equal to meters per seconds
squared. a = m/s^2. I agree that the
explanation is that it is the rate
of change of a velocity. But why is
the rate of change based on the time
parameter - seconds. Why can I not
say that the rate of change is per
meter travelled ? What if I say: a =
m^2/s. Meters squared per second, so
the travelled distance increases per
second. (?) So to use a
counter-intuition argument: this is
what we observe, time ticks the same
amount of ticks (not 1/squared), and
speed/distance increases
ANSWER:
You can certainly define a quantity
which is the displacement rate
of change of velocity , but it
isn't acceleration which is
universally accepted to be time
rate of change of velocity.
QUESTION:
My brother was taught in a
driving class that if two identical
cars collide head-on at 50 mph, that
the collision would be equivalent to
a 100 mph crash. Now, I assume the
instructor meant that the occupant
would receive the same
damage/injuries as if they had a 100
mph collision. I disagree, I believe
the damage would be the same as if
either car had hit an immovable wall
at 50 mph.
ANSWER:
I think you misunderstand the
instructor's meaning. The 100 mph
collision is if the collision is
still head-on but one car is at
rest. I will assume the collisions
are all perfectly inelastic,
i.e. , all cars and walls are
stuck together after the collision.
Linear momentum of an object is
MV , mass times velocity; keep
in mind that velocity is a vector,
so if a car is going south with
velocity 50 mph, a car going north
with the same speed will have a
velocity -50 mph. Also, if a system
has zero net force acting on it, its
momentum remains constant (momentum
conservation). If you look at one of
the colliding cars, its momentum is
not conserved because during the
collision whatever it is colliding
with exerts a force on it which
slows it down. But if you look at
both the cars momentum is conserved
because they experience equal and
opposite forces.
The initial
case the two identical cars going 50
mph in opposite directions. The
situation:
Their
total linear momentum is zero,
the magnitude of each car's
momentum is 50M
Since
they are identical, they will
crush at the same amount in
exactly the same time.
Average
force is the average time rate
of change of linear
momentum. Since magnitude of the
time rate of change of momentum
for both cars is 50M ,
the forces are all equal in
magnitude comparing the two cars
and their occupants.
Next, compare
the case of one car going 100 mph
and the other at rest:
The total
linear momentum is 100M .
After the
collision the momentum is 2MV
where V iw the
mass of both cars, stuck
together now.
V
may be determined using
momentum conservation, 100M= 2MV ,
so V =50 mph. So the
at-rest car and the 100 mph car
both have a magnitude of
momentum change of 50M ,
the same as the 50 mph in
opposite direction cars, so same
forces. So you and your brother
misunderstood the instructor's
lesson.
Finally, what
if a car hits an immovable wall?
QUESTION:
I have a question regarding
quantum tunnelling and trying to
understand how a particle can cross
a barrier and appear on the other
side. Let’s take a helium nucleus
for example that is fired at an
energy barrier. From my
understanding, the particle’s wave
function provides for a non-zero
probability of it appearing on the
other side if it is fired at a
barrier instead of just bouncing
back as is most probable. I am
having trouble conceptually
understanding the mechanics of this.
Does the particle’s ability to pass
through the barrier have anything to
do with the frequencies, ’spin’,
coherence or otherwise of the
subatomic constituents being in
phase to allow it to traverse the
barrier? If not please explain how
it can pop out on the other side.
ANSWER:
I think it important that you
understand the classical problem
where a particle encounters a force
which is represented by its
corresponding potential energy. The
figure plots kinetic (green),
potential (red), and total (black)
energies for a particle moving,
initially, in the positive x
direction. to remind you of what's
happening, I have drawn a cartoon of
the particle below but it doesn't
belong on this graph because this is
an energy vs . position
graph. So the particle moves in from
the left with a constant kinetic
energy ½mv 2
until it gets to x =0 where
it sees a linearly increasing
potential energy which corresponds
to a force in the negative x
direction; therefore it begins to
slow down and comes to rest
momentarily. Now the force starts
pushing the particle back, speeding
it up until it is now moving in the
negative direction with the same
speed it came in with. For obvious
reason the point where the total
energy is equal to the potential
energy is called the turning point;
it is classically impossible for the
party to penetrate beyond there.
Now,
let's examine same problem but using
quantum mechanics instead of
classical mechanics. Again we
imagine an incident beam moving
toward a triangular wedge potential.
Now we cannot just think about a
particle because all particles are
also waves and to understand how
tunneling works we must calculate
the particle's wave function using
the Schrödinger equation. The
particle can exist only if there is
a solution to to the equation; in
the classical case the particle
could not exist below the potential
energy because it would imply that
the particle had an imaginary
velocity. However, the Schrödinger
does have have a solution in the
classically forbidon region, it just
doesn't look like a wave; it can
therefore re-emerge as a wave beyond
the barrier, hence tunneling.
Because of nuances of quantum
mechanics, you cannot actually
directly observe the particle when
it is in the "forbidden zone". When
you are solving these equations you
must pay particular attention to the
boundaries where the wave function
and its slope must be continuous.
FOLLOWUP
QUESTION: I’m
looking over the diagrams you
provided in your explanation, which
are very helpful. Can you tell me if
I’m getting it right: Regarding the
quantum mechanics diagram it tells
us that:
the
particle’s kinetic energy has to
be greater than the potential
energy of the barrier/force, and
when the particle traverses the
barrier it loses some of its
energy in the process and
appears on the other side with a
reduced kinetic energy.
The
shroedinger equation solutions
would show us that that the
reason not all the particles
cross the barrier is that the
odds of crossing it are so small
Would it also follow then that
the greater the difference in
the energy of the particle and
the barrier, the more likely the
odds of the particle(s)
appearing on the other side
and/or in greater numbers?
If a
particle does actually appear on
the other side of the barrier -
will it have left a hole in the
barrier (if it were a physical
object) where it passed through?
ANSWER:
Note that
the vertical axis is the energy
axis, just as it was for the
classical case. The horizontal
line represents the total energy
of the particle. The wave
function, the solution to
Schrodinger equation in each of
the three regions, is drawn on
this graph even though its
amplitude is not an energy;
rather you may think of the
amplitude squared as the
probability of finding the
particle left, right, or inside
the barrier. The particle has
the same energy everywhere. The
wave function of a particle is
smeared all over this
one-dimensional space, it is
both untunnelled and tunneled
but it is liklier to be
untunneled. It may be more
usefull for you to imagine ithe
wave function as being a flux of
many particles. then the wave
function gives you the
probability that an incident
particle tunneled out.
The width
of the barrier is what
determines how likely tunneling
is. So, for my triangular
barrier, tunneling is less
likely near the bottom than the
top of the barrier. I would
rather not get into the energy
difference dependence since it
gets too technical.
Think of
it as a flux of particles. Now
it gets a littll tricky because
we have only been thinking of
the particles coming in from the
left; but particles which do not
tunnel will be reflected and
move to the left. So if you add
the tunneled flux to the
reflected flux you should get
the incoming flux.
I’m looking over the
diagrams you provided in
your explanation, which are
very helpful. Can you tell
me if I’m getting it right:
QUESTION:
I am a curious 49 year old
who has become rather obsessed with
the nature of reality. My question,
I think, concerns what counts as an
observer. For example, if we
consider a single calcium atom in
the bone of my arm. It is bonded
with other atoms.Are the 20
electrons in a superposition? Or,
because they are bonded or close to
or in a relationship with another
atom(aka "observed), they are in a
definitive position/velocity/etc...?
I think where I am eventually going
is an attempt to picture vibrations
in fields moving through the
universe. As I wave my arm in front
of my face, should I imagine
vibrations in superpositions moving
through a field? Or should I imagine
wavicles that have relationships to
other wavicles moving through a
field?
ANSWER:
You play fast and loose with the
term superposition. Regarding your
example of the calcium atom, we talk
about the superposition of all the
electrons. First let's talk about a
single atom. Because the electrons
are identical fermions in a bound
system, the wave function of the
atom must be antisymmetric*; for
your purposes, this means that the
electrons have lost their
identities, you cannot imagine a
bunch of electrons which you could
label 1, 2, 3, …40. Every electron
is a mixture of all the electrons in
the atom. (This is the same as your
superposition .) Now if you
add more atoms to your arm bone,
they bond to make the bone and it is
the electrons which are responsible
for holding the atoms together—all
the electrons' interactions form a
solid bone. In principle, the bone
is one system which must be
antisymmetrized and every electron
has a "piece" of each other electron
in your bone. Of course that would
be impossible to compute and
normally only "nearest neighbors"
are considered which surely have the
most significant contributions. And,
indeed, the electrons in both of two
atoms have pieces of all the
electrons in the pair. I do not
understand what your statement about
"observed" means and they are
certainly not "…in a definitive
position/velocity/etc…" I am afraid
everything after this makes no sense
to me.
*An
antisymmetric wave function is one
in which you interchange the
position coordinates of any pair of
particles, the wave function remains
unchanged.
QUESTION:
We pump very large amounts of
water through kevlar hose and I'm
having trouble grasping a concept.
Our MAWP (Max Allowable Working
Pressure) for 10" hose is 200psi.
This is the maximum pressure we can
safely operate at legally, our hose
is rated for higher pressure but due
to safety/legal concerns we are not
allowed to pass that threshold For
12" hose our MAWP is 150psi. My
question is Why with a larger
diameter of hose does the pressure
rating decrease? Keep in mind that
our 10" and 12" hose walls are the
same thickness.
ANSWER:
Poiseuille's law describes the
flow of a viscous fluid through a
hose of length L , radius
R ,
viscosity μ, and volumetric flow
rate F : P =8μLF /(πR 4 )
where P is the pressure
drop over the length. Everything
else being equal, P∝R -4
or P 12 /P 10 =(R 10 /R 12 )4 =0.48,
So P 12 =0.48P 10 =96
PSI. This demonstrates that it
should be less. Since I do not know
how MAWP is defined, I don't know if
"…Everything else being equal…" is a
correct assumption. If, perhaps it
is assumed that the velocity v
of the fluid is the same in each,
then the flow rate would be
F=vπR 2 and
Poiseuille's law would be written
P =8μLv /R 2 .
In this case you would calculate
that P 12 =0.69P 10 =139
PSI which is essentially what your
numbers are.
QUESTION:
Can two objects of
infinitesimal size have different
infinitesimal sizes from each other?
ANSWER:
The volume element in cylindrical
coordinates is dV =ρ· dρ· dz ·dφ .
Volume elements having different
distances from the z -axis, ρ ,
have different sizes.
QUESTION:
Clearly I am not a phycist
but I am an archmchair enthusiast
and tinker with theories. My first
question to you is that if the
universe started as a big bang, we
image that there was a zero or one
dimensional point which incredible
pressure and heat. So, it’s degrese
of freedom are pressure/girth,
expansion, possibly rotation and
heat. As it expands in the first
second, before the devolution into
the four primary forces, it
naturally loses heat and pressure.
If heat requires friction between
atomic particles or the oscillation
of electrons into higher magnetic
shells, or in some way generates
kinetic energy; How would this be
possible if there were no forms
before 1 x 10 (-17). Is it actually
heat, or an allegory? I’ve heard it
described as frenetic radiation, but
at this early-stage all we had were
photons which are massless mass.
Therefore, how was heat generated or
is it a placeholder for something
that eventually became heat?
ANSWER:
As stated on the site, I do not do
cosmology.
FOLLOWUP
QUESTION: Well that
was an enormous waste of 5 minutes.
It is not really a cosmological
question. In the absence of
particles, can there still be heat?
ANSWER:
I am not sure which of us wasted 5
minutes; must be you because I am
wasting a whole lot more (just
kidding). When I look at your
question, I see a whole lot about
the big bang and early times of the
existence of the universe, it looks
like cosmology to me. Now, I will
answer your most recent question
which need not be labeled cosmology.
The main
problem is that you do not
understand what heat is. Heat is not
energy, heat is the flow of thermal
energy usually from high temperature
to low temperature. If you look at
your question you will see that you
talk about heat as being thermal
energy. This is an important
distinction. The flow of thermal
energy is accomplished three ways.
Solids
can conduct energy because
thermal energy (in the simplest
sense) is the kinetic energy of
the atoms/molecules. So at the
hot end the particles have
oscillations larger than their
neighbors which the transfer to
their neighbors causing thermal
energy flow (heat).
Usually
gases and fluids move
macroscopically, currents,
winds, etc. This is called
convection. And, yes, without
particles there is no
convention, hence no thermal
energy flow (heat).
Finally,
all objects are constantly
emitting and absorbing
electromagnetic radiation.
Classically, EM radiation is
waves, not particles. In that
sense thermal energy flow (heat)
can occur without the presence
of particles—EM waves carry
energy. Of course you could
split hairs (and you seem like
the kind of guy who would!), and
say that EM waves are composed
of photons which we usually call
particles, but they have no
mass.
QUESTION:
We are
going to build a mobile chicken coop
so they can graze over different
parts around the farm. This is what
we are looking at: We plan on having
solar panels on the roof near the
back(above the wheels). We also plan
on having a battery bank to help
heat the water in the coop or run
fans depending on season. The
question I have is would the weight
of the batteries be better situated
higher or lower in the back of the
coop to make it easier to pick up by
the doors?
ANSWER:
I will assume that you have some
familiarity with elementary
Newtonian statics. If you don't, you
can just jump to the end for the
answer; I like to always try to show
how my answers are arrived at. The
first figure shows your coop
schematically before you try to lift
it. The battery has a weight
w which is a
distance H above the ground
and acting straight down. The center
of gravity ⊗ is where all the weight
W (except
w ) may be
thought of as acting, and is a
distance C from the axle of
the wheel. The ground exerts upward
forces of N
on the wheel and F
at the doors; the doors are a
distance D from the wheel.
We can find what the unknown forces
F and N are:
Sum of
forces is zero, F+N-W-w =0.
Sum of
torques is zero (I choose wheel
axle as axis of rotation),
FD-WC =0. (Note that w
and N exert no torque.)
Solve:
F=W (C /D )
and N=w+W [1-(C /D )].
Note that
N and F do not
depend on H .
Next you lift
at the door end until the floor
makes an angle of θ
relative th the horizontal. All
forces remain vertical (assuming you
lift vertically). F now is
the force you exert to lift the coop
rather than the force the ground
exerts at the doors. Now proceed in
the same manner as before:
Sum
of forces is zero, F+N-W-w =0.
Sum of
torques is zero (I choose wheel
axle as axis of rotation),
FD cosθ-WC cosθ+wH sinθ =0=F-W (C /D )+w (H /D )tanθ
Solve:
F =W (C /D )-w (H /D )tanθ.
Here is your answer: as
H gets larger, F
gets smaller. Therefore the
higher up you put the battery,
the easier it will be to lift
the coop. It is easy to see this
intuitively because note that
you and the battery are both
tending to rotate the coop
counterclockwise, i.e. ,
the torque from the battery is
tending to "help you out".
I have
one proviso here though: the
angle you will need to lift it
is likely small and the weight
of the battery is very small
compared to the whole coop, so
in the real world the difference
between low and high mounting is
likely to be negligibly small.
QUESTION:
I have
more of an abstract mind as opposed
to a more mathematical sort, so I'm
sure you can help me here. Regarding
Hawking radiation, virtual pairs of
particles and anti-particles
manifest and annihilate. I wonder if
that's due to the anomalous nature
of 'zero'. The formula is there
1-1=0, particle plus anti particle
equals nothing. However, by
definition, nothing can't exist.
Space is constantly trying to
resolve an equation that can't be
balanced, thus it forever 'boils' no
matter how much or how little energy
there may be. As a consequence to
this, I imagine going well beyond
the universe and Into the vast empty
space. A place so cold that only
these virtual parings can exist. In
this space no force is greater than
the other, and the 'tug' on the
fabric of space is uniform. This
makes me think about a sort of 'tug
of war' where both sides are of
equal strength. In that scenario it
isn't either side that will give in,
instead, the rope will eventually
break. This 'cosmic 'tug' would
eventually result in a massive
reaction of chaotic expansion we
think of as 'the big bang'. So, I
believe there are multiple
expansions allover the infinite
void. This might explain why the
cosmic background radiation image
was so asymmetrical. I don't have
any of the math to really back this
concept up, but I'd be deeply
grateful if you consider it.
ANSWER:
Your question makes no sense to me.
But it is not too hard to understand
Hawking energy without any math at
all. You just need to understand
what the Heisenber uncertainty
princlple (HUP) is. Secondly, if
some process can happen (that is, it
is not forbidden by any physical
law), it will happen although
perhaps with an extremely low
probability. Consider a
particle-antiparticle pair suddenly
pop into existence; are any physical
laws broken? Yes, perhaps the most
inviolable of all, energy
conservation. The pair will have
energy which was not there before
they appeared, so they have violated
energy conservation. But the HUP
says that you cannot simultaneously
know the energy of the pair and the
time it exists; i.e ., you
can violate energy conservation as
long as it exists only for the short
time which the HUP says it can
exist. When you understand these
two, go to
this link to see how Hawking
radiation works.
QUESTION:
I have a
question in the realm of mechanical
physics (I think?). I'm a quad
skater, old school style with four
wheels aligned in square pattern
rather than inline. Let's say I'm
going down a straight flat road,
build up speed and then coast on
that speed without propelling myself
forward. If I want to try and
maximize my forward force/distance
and reduce the effect of friction
slowing me down, would adjusting the
amount of wheels in contact with the
ground make a difference? Part of me
feels that if I can balance in two
of the 8 wheels, there's less
contact with the surface of my
wheels and the ground, meaning less
friction. But, the distribution of
my weight across that surface of
contact is far less, meaning there
would be greater friction anyway.
Which feels like a conservation of
energy sort of thing but it's been a
while since I've been in a physics
class. So, my question is
ultimately, is there a technique
where I could reduce friction and
maximize distance by adjusting the
amount of wheel on the ground, or is
physics laughing at me for trying to
outsmart it?
ANSWER:
It is a fact that the frictional
force is proportional only to how
hard two surfaces are pressed
together and depends on the nature
of the surfaces (e.g .,
there is a lot less friction from
steel sliding on teflon than steel
sliding on rubber.) The force
pressing your wheels to the ground
is equal to your weight and it makes
no difference the area over which
you cause that force to be
distributed. I would guess that the
air drag would more important in
slowing you down than the rolling
friction of your wheels; the drag is
proportional to the square of your
speed and the area you present to
the onrushing air, so you could
minimize the area by squatting down,
thereby maximizing the distance.
QUESTION:
Say you
have 2 masses separated by a
distance of 1 lightsecond. Mass A
begins moving away from B (relative
to their common fixed inertial
frame). Will B feel a weakening
gravitational force from A
immediately or starting 1 second
later? A from B?
ANSWER:
Although the speed of gravity has
not been measured precisely,
everybody assumes it is the same as
the speed of light and many
measurements indicate that it is so.
Therefore, B will not observe any
change in the field for a second,
the same time he would have to wait
to see A depart. A will observe the
same sequence of events.
QUESTION:
If a
rocket were to take off vertically
from earth and travel in a straight
line away from earth at 10000 mph
continuously for an indefinite
amount of time with unlimited fuel
what would happen? Escape velocity
is 24000ish mph so it shouldn’t get
into outer space, but it is always
maintaining a tremendous forward
motion. Would it hit an imaginary
wall and just hover at the same
point in the sky as the earth
rotates under it, would it maintain
the same height but orbit with the
earth or would something else happen
all together? This is assuming that
the nose of the ship is pointed into
outer space and its trajectory never
changes. For directional sake say
it’s taking off from the very center
of the North Pole or whatever the
highest point on earth
longitudinally is and it keeps
flying away from the earth where
would it go?
ANSWER:
You have evidently never had a
physics course. I am going to assume
there is nothing we need to focus on
in the whole universe other than
your rocket and the earth. (I ignore
any forces from the sun, any planets
you might encounter, any stars you
might encounter, etc .) The
escape velocity is the speed which
the rocket must start with at the
surface of the earth if your engines
never fire again; this rocket would
immediately start slowing down
because of the gravitational pull of
the earth on it and continue slowing
down until at an infinite distance
where it would stop. Now, your
rocket starts at some constant value
(it would not have to be large,
maybe just 100 mph) because the
force the engines give it are always
adjusted so that it is exactly the
same as the gravitational force
trying to slow it down. Eventually
you would get so far from the earth
that the force trying to slow it
down is maybe one ounce. Except for
an occasional tiny pulse from your
engine you could coast almost
forever and use almost no fuel.
QUESTION:
Many
experiments have been done
bombarding protons with energetic
electrons. Most results appear to be
focused on how the electrons bounce
or recoil off the protons or their
imputed constituents, perchance to
illuminate what's in the proton.
Have any experiments been done
focusing on how many (what %) of
bombarding electrons pass directly
through the proton without bounce or
recoil? Or is it impossible to
determine whether any do? I would
appreciate any light you can shed on
this. Perhaps how narrowly the beam
is focused and the density of
protons in the target mean one can't
distinguish between electrons that
missed all the protons in the target
entirely, and those that might have
passed through the protons.
ANSWER:
This is not a collision of classical
billiard balls, it is an
electrically charged electron
interacting with a charge
distribution. "Bounce or recoil"
really has no meaning in this
context because the electron has no
option other than to interact with
the field. What can happen is that
the electron might exit without
changing the the state of the
nucleus; this is called elastic
scattering and the electron could be
scattered at any angle including 0°.
In fact this is, by far, the
likeliest thing to happen.
QUESTION:
I am a
newbie to electricity and magnetism.
I am confused about 1 electron
charge is 1.64x10^-19 Coulombs and
1Coulmbs = 6.24x10^18 Elementary
charge Unit. First of all what does
it mean by elementary charge unit
and what is the difference between
two values 1.64x10^-19 and
6.24x10^18.
ANSWER:
First of all, one of your numbers is
wrong, 1.64x10-19 should
be 1.602x10-19 . All
electrons have an electric charge or
e =1.602x10-19
C/electron where C is the unit of
electric charge, the Coulomb. Until
recently the Coulomb was defined in
terms of an Ampere (A) which is the
unit of electric current; 1 C=1 A/s
(s is second). An Ampere was defined
in terms of the force which two long
parallel current carying wires
exerted on each other. This was
always difficult because it was just
too convoluted. Recently the SI unit
of electric unit was redefined as
the magnitude of the charge of
something which contained as N
electrons of charge e such
that Ne would be equal to a
Coulomb: 1 C/electron=N x1.602x10-19
C/electron. Solving, N =1/1.602x10-19
=6.242x1018
electrons/Coulomb. (Coulombs per
electron is the reciprocal of
electrons per Coulomb.) This is now
how the Coulomb is defined, the
magnitude of the charge of 6.242x1018
electrons.
QUESTION:
Years
ago, I used to listen to the NPR
Saturday radio program "Car Talk"
They always had a puzzler question
that they asked (new puzzle) ant
then answered the prior week's
puzzel later in the program. A
puzzler was asked that I never heard
the answer to. I'll try to repeat as
much of the details as I remember. A
guy is floating in outter space and
is "buck naked". He is within reach
of two iron bars. One is magnitized
and the other is not. How can he
tell which bar is magnitized? They
didn't say it, but I presume that
the non-magnitized bar would be
attracted to the magnitized bar, and
vice versa. That's as much as I
remember. I have wondered for years
what the answer was but searches of
NPR "Car Talk" website only turn up
re-plays of the radio programs and I
don't know the dates of broadcast
where I might be able to listen to
the next-week's program to hear the
answer.
ANSWER:
Wow, I loved Car Talk. I really miss
those two guys. I have had a couple
other questions involving that
show*. Now, the iron bars puzzler,
two identical iron bars but one is
magnetized, the other is not. How to
find which is which. I must admit
that this took a little thought to
come up with the answer. Look at the
figure below. If you grab the
magnetized bar it exerts the same
large force, always attractive,
wherever you bring it up to the
other bar. The pictures all look the
same if the south pole is up. Now,
if you pick up the unmagnitized bar,
the same force will be found at the
ends; but at the center there will
be only a very small force.
Other
mentions of car talk are at
carstuck ,
pickup ,
saltwater .
QUESTION:
I would
like know what affect solar flares
have on the earth's orbit. Since we
talk about solar sails as a means of
propulsion, wouldn't that mean the
solar wind pushes against the earth
as well?
ANSWER:
In principle, yes. In the real world
it is negligible because the earth
is so massive; there would be no
observable effect on the earth's
orbit. A more interesting question
is why aren't we getting mortally
fried by all the radiation we should
be exposed to? Actually, the earth's
magnetic field serves like a shield
to protect us from the solar wind.
So most of the solar wind which
would have hit us is deflected by
the magnetic field and ends by just
flying by. Still, some gets through
and is responsible for the northern
and southern lights. The intensity
of the wind fluctuates a lot. I have
read that, because the orbits of
satellites which GPS uses must be
known to extraordinary accuracy, the
orbital calculations are crucial;
the biggest errors in GPS results
come from when the solar wind is big
and it does affect these orbits and
it is not as not possible to know
when the satellites will be
affected.
QUESTION:
I
recently thought of this question
that I could not confidently answer
myself, and I have googled as well
to no avail. I apologise if this
question seems trivial, but I am
hoping to be blessed with some of
your knowledge. The question is: How
does visual and tactile nerve input
match in our perception? For
example; if I tap the back of my
hand, I see it happening instantly,
and feel it happening at the same
time. The pathway of course as you
know is light hitting the back of my
retina, then having that nerve
impulse travel through the optic
nerve towards the brain, while the
nerve input from the back of my hand
does the same as well. And
apparently, nerve impulse conduction
velocity does not even come close to
the speed of light. Is it because of
the differing lengths of the nerves
involved allowing them to somehow
match each impulse upon arrival in
the brain? I thought of this, but it
feels so simple and incomplete.
ANSWER:
This is really neuroscience, but I
can give you the physics slant on
the question. I looked up what the
speed of nerve impulses: the speeds
range from about 0.5 to 120 m/s.
There are two kinds of nerves,
myelinated and unmyelinated. The
myelinated are in the peripheral
nervous system and have generally
much bigger speeds than the
unmyelinated. So, let's just suppose
the speed of the impulse carrying
the information of feeling the tap
is 120 m/s. The distance from your
hand to your brain is about one
meter, so the time is about 0.0083
s. I am sure that the time until
your brain sees the tap is about the
same. But I don't think that your
brain can comprehend a time interval
that small.
QUESTION:
I was
watching a film starring Arnold
Schwarznegger and when explaining
the futuristic weapons (90s film),
an actress said the bad guys were
using railguns as rifles. When I
looked it up on google, it said that
the concept was not viable. If it
can be done and built as a rifle;
what challenges do we need to solve
and if not what are the unsolvable
problems ?
ANSWER:
I have already answered a question
almost identical to yours. You can
see that answer
here . There are also links to
several more questions "about sci-fi
and video games guns" on the faq
page.
QUESTION:
The
fabric of spacetime itself is
expanding exponentially. This would
imply that eventually there will be
an amount of spacetime with
absolutely nothing within its
volume. Eventually this area would
be a complete void being too distant
from any interaction with anything
whatsoever. Not a neutron, not a
photon or anything. Absolutely
nothing. What kind of events would
occur in such an environment?
ANSWER:
Actually, most of the universe
already satisfies your criterion:
intergalactic space contains
approximately one particle per cubic
meter. So you would have no trouble
finding some cubic meter where there
is nothing inside its volume, a
perfect vacuum. Since there is no
mass and no field inside your
volume, the total energy in that
volume is zero. In classical physics
you would say that the total energy
remains zero forever, energy
conservation (no external forces
doing work). But there is something
which says that energy conservation
can be violated as long as that
violation exists for a short-enough
time—the Heisenberg uncertainty
principle which can be applied to
energy and time, ΔE Δt ≤ℏ
for example, if an M =5 kg
bowling ball popped into existence
that would be ok as long as it
disappeared before a time Δt =ℏ/ΔE
where ΔE =Mc 2 =5x(3x108 )=4.5x1017
J and ℏ=1.05x10-34
J·s, so Δt =4.7x10-51
s. So a big mass would exist an
impossibly short time. What normally
happens is that a
particle-antiparticle pair, say an
electron-positron pair, pops into
and promptly out of existence. This
is what is called virtual pair
production and you cannot observe it
directly. However, if you do some
electrostatic experiment in a
perfect vacuum you will not get the
correct answer unless you account
for the virtual pair production
processes. This is why this is
sometimes called vacuum
polariztion .
QUESTION:
Someone
originally posited the question: "Is
it possible for two different balls
of identical mass and velocity to
have different kinetic energies?" At
first I agreed with most others that
it was impossible and used the KE
equation as the basis for my
opinion. After some thought however,
I came up with a scenario that makes
me question this as follows: Imagine
two spheres of identical masses, one
with an internal void space of some
amount. Impart to them both a spin
and a velocity, both of which being
equal. Now if you were to measure
the KE of the homogenous spere as it
moves, it would be a constant as one
would expect. With the spere with an
internal void spinning as it moves
along its path, would this not
create a kinetic energy level whose
vale plotted on a graph would look
like a sin wave whose frequency
would match the spheres rotation and
the amplitude would be a
relationship between the total
volume of the sphere and the amount
in the void space. I think I belive
that thte kinetic energy problems I
have done all assumed the center of
the item I was calculating for as an
easement of solution. I think that
if the ball is psinning under these
circumstanes you would have t
consider the sphee having a 'moent'
that you have to calcullate its
position for insead of the center
and thus the sin wave effect. Am I
close to the solution or is it truly
just the KE equation regardless of
what is going on iwthin the mass?
ANSWER:
You have the answer, but it is not
necessary to go through all the
stuff about voids, sine waves,
etc . You simply say that one
sphere is spinning as it also moves
with speed v . Even a ball
not having a translational speed at
all but spinning has kinetic energy.
The total kinetic energy of rotation
is K rotation =½Iω 2
where I is the moment of
inertia of the rotating object and
ω is the angular velocity.
So if one of the balls is spinning
it has more kinetic energy than the
other. If both balls are spinning
with the same angular velocity, the
kinetic energies could still be
different because of the moment of
inertia. For example, the moment of
inertia of a uniform solid sphere is
2MR 2 /5 and of a
hollow spherical shell 2MR 2 /3.
QUESTION:
My
question is about how torque and
power each contributes to the
performance, and acceleration of a
car. The acceleration should be
equal to the force the wheels pushes
the road with, devided by the mass
of the car. The force is determined
by the torque of the engine if i’m
not mistaken. On the other hand,
acceleration of a car can be
described as the accumulation of
kinetic energy, given constant mass
of course. The rate of that is
determined by the power delivered to
the wheels. My hope is that you can
give me a better understanding of
«torque vs power».
ANSWER:
You are right, the force which
accelerates the car is the
frictional force between the road
and tires. But, performance-wise,
what matters is how quickly the
engine can transmit energy to the
wheels. In physics, think first of
force: Force is what you need to do
in order to give some mass an
acceleration. Torque is the rotation
analog of force, that which you must
do in order to give some object an
angular acceleration—for example to
increase the angular speed of a gear
from 5 rpm to 10 rpm. Torque is
defined as product of the force
F times the distance from r
from the axis of rotation, T=rF ;
if you double the torque in a
particular situation, you will
double the rate at which the
rotational speed (RPM) increases.
Torque for a combustion engine
usually envisions the drive shaft as
the agent for delivering torque from
the engine. But you really cannot
just say that a particular engine
has a particular torque because the
torque depends on many variables
such as the RPM of the engine and
also on the gearing between the
drive shaft and the wheels. Now, the
engine delivers energy to the car at
some rate. If something is
accelerating in a straight line, the
force F times the velocity
v is the power P ,
P=Fv . For example, suppose
you want to see what force is
required to deliver P =200
horsepower (hp)=1491 watts (W) at
the speed v =50 mph=22 m/s;
F=P /v =1491/22=68
N=15 lb. Now the same thing can be
done for delivering energy to a
rotating object with a torque: The
torque required to deliver power
P to something with a
rotational velocity ω is
given by the equation P=Tω ;
in this equation P is
in N·m/s, T is in N·m, and
ω is in s-1 .
I presume you would like to
work in RPM and horsepower, so
making those conversions,
P =(2π (ω /60)T )/746,
with ω in RPM, P
in hp, and T in N·m.
T =7114(P /ω ).
So if you
want to know how many N·m of torque
you need to generate 200 hp at 1000
RPM, it is 7114x200/1000=1423
N·m=1050 ft·lb.
QUESTION:
If light
slows down ( I appreciate it is by
very little ) in water what speed
does it travel at after leaving the
water and entering a vacuum again?
If it returns to c then where does
the extra energy come from to speed
up again? If it does not return to c
then does that not mean that the
only light in the universe
travelling at c is light that has
never been slowed down by anything
else? This came up in a conversation
with some friends ( we have weird
conversations ) I have a sneaky
feeling that it will be some special
case because of the nature of light
( being massless? ) that means
conservation of energy does not
apply. Could you explain in terms a
55yo with a degree in maths ( not
physics ) can understand?
ANSWER:
Let's
start with a fundemental fact about
waves: the speed of a wave v
equals its wavelength λ
times its frequency f ,
v =λf . I assume you
know what wavelength and frequency
of a wave are. Now imagine a very
long string which we are wiggling at
one end with some frequency some
frequency f . So there will
be waves of frequency f
traveling down the string. The speed
of waves on a string depends on the
mass density of the string (grams
per meter, for example) and the
tension in the string, how taut it
is. Now, suddenly the mass density
gets bigger at some particular
location on the string, so at that
point the wave on the new part of
the string, while still vibrating
with the same frequency as the
lighter part of the string, moves
more slowly. As a result, the
wavelength gets shorter. Note that
no energy leaves or enters the wave
when the speed of the wave changes.
If the string becomes lighter again,
the waves will speed back up again.
Light behaves
the same way, slowing down in the
medium and speeding back up at the
interfaces with the vacuum. The
difference is the mechanism for
slowing the waves down or speeding
them up; v =λf
still holds. There is another way
you can look at light: You may know
that light waves of some given
frequency may be thought of as a
swarm of photons, each having an
energy E=hf where h
is Planck's constant. Since f
is the same in and out of the
medium, the photons always have the
same energy whatever the wavelength
of the corresponding waves.
QUESTION:
(the
video holds my try to solve a
textbook question with my intuition,
it's not about how to solve a
textbook question but rather it is
that whyy my intuition is incorrect.
Although it's not necessary to watch
a video of me struggling to solve a
problem and in the end get the wrong
answer.) Sir it's not about the
textbook question.. but I am asking
that why is equivalent mass of a
pulley system (the mass of a block
by which we can substitute the whole
pulley) different than, the (m1+m2)
where m1 is mass at the left side
and m2 is mass at the right side of
the massless, frictionless pulley.
Whyy is it not m1+m2 because I only
see that much mass there on the
pulley And in the equivalent mass
formula, 4m1m2/(m1+m2) Where does
some extra mass come from??? Well,
if we measure the weight of the
whole pulley system, it should be
(m1+m2)g !! And not 4gm1m2/(m1+m2)
right? see some say that the tension
in the upward string that is holding
down the whole pulley system will
depend on the accelerations of
masses happening inside the pulley,
But Those are internal
accelerations, and if one block goes
up, the other one goes downand
therefore balancing the
accelerations. Can you please solve
the confusion on the equivalent
weight of the whole pulley being
different then the actual weight of
the pulley??? Why is it different?
ANSWER:
I have not posted the video because
it is not informative except to tell
me what the problem is. Also, this
is not a tutoring site so I have no
intention of trying to figure out
what the questioner is doing wrong.
So I have not even actually read his
question in any detail. It is
obviously wrong and I will outline
how to get it done correctly. We are
given that m 1 is
at rest. The questioner then was
correct in his reasoning that the
tension in the thread connected to
m 1 must be m 1 g
and it will be the same on both
sides of the upper pulley. He then
seems to think that the whole
lower pulley sistem can be thought
of as an object of mass m 2 +m 3 .
This is only true if those two
masses are equal. If they are not,
then one accelerates down and the
other up and all bets are off, you
cannot do the problem that way.
(Whoops, I just did what I said I
wouldn't—tell him what he was doing
wrong!) The first thing to do is to
look at the lower pulley. There is
an upward force m 1 g
and two downward forces which must
be equal in magnitude which I will
call T ; the pulley must be
in equilibrium, so T =m 1 g /2.
Next I will look at m 2 .
I will choose the +y
direction to be vertically up and so
m 1 g /2-m 2 g =m 2 a 2
where
a 2 is the
acceleration of m 2 .
Next I will look at m 3 .
I will choose the +y
direction to be vertically down and
so
-m 1 g /2+m 3 g =m 3 a 3
where
a 3 is the
acceleration of m 3 .
But the magnitude of the two
accelerations must be the same so
a 3 =±a 2 .
Since I have chosen +y to
be in opposite directions, a 3 =a 2 =a .
If you now solve the two equations
(eliminating a ) you will
find [4/m 1 ]=[1/m 2 ]+[1/m 3 ].
QUESTION:
I'm a
recent physics graduate, and I've
realized that most of what I've done
while studying physics is very
theoretical, with the exception of
some basic kinematics, circuits, and
optics labs. However, if at all
possible, I would like to perform an
experiment to show Relativity (or at
least the underlying postulates) in
the real world for myself. After
all, it's different enough from our
everyday experience to be difficult
to accept on an intuitive level,
even if you learn the math and such.
I figured I'd ask around and see if
you had any ideas for such an
experiment using either materials
you can find at home or basic
undergraduate lab equipment.
ANSWER:
Well, I
couldn't think of a table-top
experiment which would meet your
criteria. So I did a quick Google
search and found a question
basically the same as yours on
Physics Forums . I think you will
find the ensuing discussion
interesting but probably nothing
which would fit your wishes.
QUESTION:
Hello,
I'm another 11th grader and I'm
trying to understand how EM waves
work. The electric and magnetic
waves are in the same phase.
However, I was told that during
induction the changing magnetic
field induces the electrice one, and
vice versa. From this I'd assume
that B is shifted by compared to E,
supposedly being its derivative, but
that's not the case. I looked some
things up on ChatGPT and the
internet and found the following
Maxwell equation: After getting a
rough understanding of gradients and
partial differentiation (took a long
time), I concluded that the rate of
change in the electric field equals
the negative rate of change of the
magnetic field (divided by the
change in time). Which still doesn't
make sense! If E and B change
alongside each other (beside some
constant, or directional
difference), then charged objects
would gain a constant magnetic field
and freshly magnetized pieces of
iron would gain an electric field,
which they could keep, until their
magnetic field declines.
Besides the
former, I'm struggling at
understanding how energy is stored
within photons, if E and B oscillate
at the same time. Due to how
inductors and capacitors can be
charged, I am of the opinion that
electric and magnetic fields contain
energy, like in this equation about
energy density: However, if E and B
reach zero at the same time, that
would mean the photon has no energy,
which it clearly has, when E and B
are at their maximum. This goes
against the conservation of energy,
which means I'm really missing
something. Can you help me in this
regard?
ANSWER:
[This
question had equations and a figure
which I have edited out because I do
not do LaTex symbol language. Also,
because the questioner is not really
prepared to understand
electromagnetism at this level.]
I admire
your quest to understand
electromagnetism. You are already in
a good place in understanding
qualitatively. Until you have
studied vector calculus and
differential equations, however, be
satisfied that you have already
achieved way beyond your years. I
will briefly give you some more
information to help with your
pursuit of this difficult subjece.
The first equation you show is ∇xE =-∂B /∂t .
This is not a gradient of
E , rather a
curl of E .
So you need to understand the curl
operator to understand the relative
phases of E
and B .
The other
equation you quote (corrected here)
is energy density of an
electromagnetic wave,
U =½(ε0 E 2 +B 2 /μ 0 )
in empty
space. What you are missing is that
this equation has been
time-averaged. And before it is time
averaged any spot in space would be
oscillating between 0 and some
maximum value; there is no violation
of energy conservation as you
suggest. Regarding the photons, this
is not what the energy density is
for them. If the frequency of the
wave is f then the energy
of one photon is hf where
h is Planck's constant.
Hence, for photons U photons = Nhf
where N is the number of photons per
unit volume. In both cases U
has units J/m3 .
QUESTION:
For the
past several months, I (an aerospace
engineer with an interest in quantum
mechanics) have been trying
understand Heisenberg's frame of
mind when he first came up with his
crucial insights in 1925. Everywhere
I look I see essentially the same
statement: "His leading idea was
that only those quantities that are
in principle observable should play
a role in the theory, and that all
attempts to form a picture of what
goes on inside the atom should be
avoided." What none of the sources
has conveyed to me is the following:
granted that at the time Heisenberg
developed his theory there was not a
microscope powerful enough to see
individual particles within the
atom, but how did he conclude that
seeing the positions and motions of
the particles was "in principle"
impossible? This was two years
before he derived the Uncertainty
Principle, which in any case is
predicated on his original
derivation of quantum mechanics. So
without any of that "knowledge," he
just arbitrarily decided that some
quantities which had not yet been
observed were in principle
unobservable? I don't understand
that. Can you help me?
ANSWER:
Your
question is strange. What does
"Heisenberg's
frame of mind" even mean? Anyhow,
that isn't physics, that's history
of physics or maybe psychology of
physics. In 1925 Heisenberg
constructed the first mathematically
rigorous theory of quantum
mechanics; it was based on matrix
algebra. Prior to that there was
only the Bohr-Sommerfeld
semiclassical description of what I
refer to as quantum physics. Within
a year an alternate theory, based of
differential equations, the root
being the Schrödinger equation which
is a wave equation. The latter was
generally more accessible to
physicists and is the favored theory
to introduce to students for that
reason. Still, Heisenberg's quantum
mechanics is very elegant but more
difficult to calculate with. But the
two were subsequently shown to be
100% identical in rigor and both
describe the exact same physics.
What is different is the mathematics
used by each.
The
uncertainly principle does not say
some quantities are unobservable. It
says that some pairs variables are
'conjugate variables' and therefore
you cannot measure both to arbitray
good accuracy, you cannot know both
of them exactly. It is actually
built right into quantum mechanics,
so no 'arbitrary' decisions needed
to be made.
I think you
should give priorty to learning
quantum mechanics rather than
Heisenberg's state of mind.
QUESTION:
Is it
possible for a person to jump/drop
onto an impact force measuring
device and have the initial impact
force be less than body weight?
Reference/context: Science world had
a kinesiology exhibit, and one of
the displays was about impact force
measurement. The person gets weighed
and then climbs up to a platform
approximately 18-24 inches high. The
person then jumps/drops down onto an
impact force measurement device, and
a display shows impact force by body
weight. After a couple attempts I
achieved an impact force reading of
1.2 times my body weight, and I feel
I could have done better. Could that
number have been below 1.0?
ANSWER:
I need to
know what the device actually
measures. "Impact force" is not a
quantity in physics. A force is a
force, but an impact is the product
of a force times a time. For
example, if you have a mass m ,
hit the device with a speed v
and come to a stop in a time t ,
your average impulse over that
interval is I=Ft=mv . where
F is the average force you
feel during the collision time. So
you could write F=mv /t.
I suspect that F is
what this device measures. Assuming
m is some fixed number, how could
you control how big or small F
is? If you increase v or
decrease t , F will
be bigger; if you decrease v
or increase t , F
will be smaller. An everyday example
is consistent with this: If you fall
and hit your head on a cement
sidewalk, you might get badly hurt
because your head stops in a very
short time; if instead you fall on a
thick foam mat, you would probably
not get hurt because it takes a
pretty long time to stop.
So let's see
if there is a way to get an F
which is less than your weight.
Being a scientist, I must use SI
units, but I will try to convert to
Imperial units when it seems
helpful. Mass is measured in
kilograms (kg), length in meters
(m), and time in seconds (s). So
suppose that your mass is 100 kg,
the height is 0.5 m, and the time is
t . ; acceleration due to
gravity is about g =10 m/s2
so your weight is W =1000 N
(a newton is mass times g
and is 1 N=0.224 lb). So, your
weight would be about 224 lb. since
v/t is your acceleration, I finally
come up with F /W=a /g
where a is your average
acceleration. So you just need to
have the rate at which you are
slowing down less than the
acceleration due to gravity. If you
drop from 0.5 m your speed when you
hit the device is about v =3.16
m/s. So if you can make v /t =10,
F /W= 1.0, so t =0.316
s. If you make the time greater than
about a third of a second you will
get below 1.0; you can do that by
watching what parachutists do when
they land—go into a crouch as slowly
as you can. Of course, I do not know
how the measuring device works so my
numbers may be off, but anything you
can do to increase the time from
when you hit and when you stop will
lessen the average force
you feel.
QUESTION:
When
Hiroshima and Nagasaki where bombed
with nuclear weapons in World War 2
there was total devastation. However
within a relatively short period of
time people were able to move back
in and re-build the cities. However
when there is a nuclear power plant
meltdown like Chernoble or Fukushima
the area around the power plant
remains contaminated with
radioactivity for thousands of
years. Why is that?
ANSWER:
I have
previously
answered this question.
QUESTION:
I'm
having trouble with Hawking
radiation. It seems to me that if
you separate a pair produced at the
"event" horizon, with one half of
the pair falling into the black hole
and the other half escaping, you
have added mass\energy to the black
hole rather than subtracted from it.
The problem for me here is the
assumption that the mass\energy to
produce the pair in the first place
is somehow subtracted from the black
hole?! To me this seems to
presuppose that the mechanism for
the pair production is well
understood and the reservoir for the
mass\energy for this pair production
can communicate across the "event"
horizon.
ANSWER:
AI have
answered this question before.
QUESTION:
Red
shift/blue shift—light traveling
toward us (Andromeda Galaxy as an
example of blue shift) has a shorter
wavelength than stars/galaxies that
are moving away from us. These light
waves are part of the visible part
of the electromagnetic spectrum
(right?), but what about the parts
that are invisible to the
eye—ultra-violet, infrared, radio
waves, etc? Do these waves change
frequency in the above examples? (I
know about Doppler radar and how it
works, so is the same principle at
play here?)
ANSWER:
All frequencies
of electromagnetic waves are Doppler
shifted.
QUESTION:
Black
holes because of their mass and
gravitational 'pull' suck things in
and there is no escape (at least as
I understand it), and this includes
light. But light has no mass, so
what is it about light that makes it
susceptible to the gravity of a
black hole?
ANSWER:
Our best theory
of gravity is general relativity. In
general relativity a photon, the
quantum of the electromagnetic
field, has energy. (Of course it
does because the electromagnetic
field itself has energy.) The energy
E the photon has is
E=hf where h is
Planck's constant and f is
the frequency of the field. If you
throw a ball straight up in the air
with some initial speed v ,
it initially has energy E =½mv 2 ,
but the higher it goes the smaller
v becomes until it is zero;
so when it runs out of energy it
stops and, like any mass, will fall
back to the ground. The photon,
however, still loses its energy but
in another way: Because of the red
shift of light moving away from a
heavy object, the photon's frequency
will get smaller as it rises. For
most objects, a star for example,
the photons will end up with a
pretty small shift in frequency. For
a black hole, however, the photon
loses all its energy before it can
escape, that is, it simply
disappears. If you are wondering
where the energy of the photon went,
it went to increasing the mass of
the black hole by an amount m ,
mc 2 =hf
or the mass of the black hole has
increased by m=hf /c 2 .
Incidentally, There are two kinds of
red/blue shifts. One is the one you
are probably familiar with,
generally called "Doppler shift" and
caused by motion of the source or
observer. The other, as discussed in
this answer, is referred to as
gravitational red/blue shift.
QUESTION:
I've
just generally been thinking about
this for a while, and it's difficult
to get an answer from Google. I
think if I understand things
correctly, it's actually vital for
our universe that the speed of light
is constant, and this constant
effectively creates the
electromagnetic spectrum we observe.
Light can't go faster. It can only
increase in frequency as more energy
is added. If there was no constant
speed of light, it might be the case
that all energy in the universe
would evaporate instantly? Maybe? I
don't know. I'm just trying to
conceptualize what's going on. But
what would be the physical mechanism
by which the speed of light is
constant? It must be a property of
space? Do physicists have a solid
understanding of what causes this?
ANSWER:
Go to the faq
page. You will find "Why
is the speed of light constant to
all observers? "
QUESTION:
I am an
11th Grade Student, and my teacher
currently teaching us newton's laws
of motion, in the above image there
is a pulley arrangement, with all
surfaces smooth! my teacher was
discussing about this in the last
few minutes of school and i couldnt
understand it. He said that the big
10kg block will move towards the
left! what? why would it move
towards left? it would need a force
in the left direction right? but
here, i dont see any force on the
10kg block which is on left
direction... [followed by 364
unnecessary rambling words!]
ANSWER:
Once
again I am faced with a question
which violates site ground rules
requiring "...single, concise,
well-focused questions." Oh well, I
have just edited it down and, rather
than doing a complete solution, I
shall only address the student's
primary concern: when released, what
happens to the 10 kg block? I always
told my students to "choose a body"
when starting a Newton's second law
problem. I choose the pulley which,
although not stated explicitly, must
be frictionless and massless. The
next step is to find all the forces
on that body . Clearly the
string is pulling on the pulley to
the left by T 1
and down by T 2 ;
because this is a massless pulley we
can assume T 1 =T 2 =T.
But, wait, is there anything
else touching the pulley which might
exert a force on it. Yes! This setup
would not work if the pulley were
not attached to the 10 kg block. The
block must therefore exert some
force on the pulley to hold it on
the corner of the block,
F in my diagram.
If the block exerts a force on the
pulley, the pulley exerts an equal
and opposite force on the block, and
that force has components to the
left and vertically down. One more
thing: The questioner indicates
that, when the system is released
and the two 5 kg masses start
accelerating, the tension is the
string is 5g . This is
wrong.
QUESTION:
My
question is about the way steam and
heat works when food is cooking. For
instance, if you cook food too long
in a steamer, the food generally
gets mushy if cooked too long.
However if you heat up food in an
airtight container in the microwave,
the food does not get mushy if
cooked for too long. In fact it will
burn and get crunchy instead,
despite having steam and lots of
moisture in the container. Is there
a physics-related reason that the
two steaming methods vary so
drastically in outcome if
overcooked?
ANSWER:
In a
steamer there is a reservoir of
water continually adding stream to
the inside of the pot. The cooking
happens from the outside in. If you
cook too long it will be overcooked.
The same happens simply boiling the
food. When you microwave you heat up
the whole thing uniformly. And any
steam that is in there came from the
food itself, not nearly as much as
in a steamer. But if you do that too
long you will boil the water out of
the food and it will certainly
become "crunchy".
QUESTION:
I need
to move an 80 pound speaker 28.5
inches above the floor using a dolly
on a 7 foot long plank. How much
force will I need to apply? (A very
long question heavily edited by me!)
ANSWER:
Before you push there are two forces
on the speaker, its 80 lb weight
(red force in the figure) which
points straight down, and the force
which the plank exerts on it to keep
it from breaking through the plank
and which is perpendicular to the
plank (the green force in the
figure). There is also a frictional
force which is parallel to the plank
and pointing up the plane; because
you have managed to put the speaker
on wheels, this force is negligibly
small for our purposes. When doing
inclined plane problems it is useful
to resolve all forces into
components parallel and
perpendicular to the plane; these
are shown by the dashed forces. I
won't go into detail about resolving
forces here, but these two
components are completely identical
to the 80 lb force and show us that
there is a 27 lb force trying to
push the speaker down the plane and
a 75 lb force trying break the
plank. The plank is strong enough so
the plank doesn't break; but if
nothing (this is where you come in)
intervenes, the 27 lb force will
accelerate the speaker down the
plane. If you now push up the plane
with just a little more force tha 27
lb, it will go up the plane, as you
wanted it to do, instead.
QUESTION:
You have
4 hot hard-boiled eggs you want to
cool down quickly. They are in a
pot. You throw in a handful of ice
and then add cold water. Do you just
cover the eggs with the water or
fill the pot? Which is faster?
ANSWER:
I want to
start out by noting this is an
academic question. The way cooks
normally cool hot foods quickly to
halt the cooking is to plunge the
hot food into an ice bath, water to
which enough ice has been added to
bring the temperature of the water
down to 0°C (ice water).
This can
get to be a very complicated system.
I will simplify it to include only
what is going on with the water,
ice, and eggs. In other words,
imagine that these three are
enclosed in an insulating box
through which heat cannot flow. This
is probably a good approximation
because cooling the food happens
quickly enough that the interaction
with the bowl and air in the room is
minimal. What happens is:
ICE:
There
are two ways ice can absorb
heat: (a) if the temperature is
less than 0°C, it can warm up
until it gets to 0°C, and (b) at
0°C it will absorb heat but not
increase in temperature, instead
melt. Most home freezers have a
temperature of 0°F=-18°C, so
initially, the way the ice will
absorb the energy is by warming
up; when the ice reaches 0°C it
will absorb energy by melting.
WATER:
The question seems to ask,
mainly, how much water should we
add. I will look at several
amounts of water. I will start
the water at 15°C, a typical
temperature for tap water.
EGGS: The
mass of an egg is about 50 grams
and we have four of them. They
have just come out of boiling
water at 100°C.
I struggled
with answering this question. The
main problem is that the speed at
which the temperatures change
depends sensitively on things like
how heat diffuses from the centers
of the eggs into the water and the
size of the pieces of the "handful
of ice"; crushed ice will absorb
energy much faster than a big block
of ice. So I cannot answer the
question, which presumes that only
the amount of water determines the
speed to come to equilibrium—there
are many more factors which play. I
think it likely that it would take
longer times for large amounts of
water to come to equilibrium, so I
could glibly suggest that the answer
is the smaller amount of water is
faster; but the problem has too many
variables to know for sure. What I
have decided to do is demonstrate
the physics of how the final
temperature T is achieved
and work that out for one example: I
will find the minimum amount of ice
we must add to 1 liter of water so
that the equilibrium of the
ice/water/eggs system will be T =0°C.
Heat is just
the flow of energy. If an object has
a mass M and a temperature
T 1 and an amount
of heat Q is added its
temperature increases to T 2 .
Then the change of temperature is
proportional to Q , Q =MC (T 2 -T 1 ),
where C is a
proportionality constant called the
specific heat of the material
absorbing energy. If the object is
instead having energy taken from it,
T 2 -T 1 <0
so Q <0. If a solid is
melting it is absorbing energy but
not getting warmer; in that case one
needs a constant called latent heat
of fusion, L which is the energy
absorbed per kilogram of material
melted, Q=ML. So, the
following is the computation.
and the
latent heat of
fusion
for:
ice:
L =3.33x105
J/kg.
I will
calculate the amount of ice which is
needed for the final temperature to
be T =0°C starting with 1 kg
(a liter) of water.
M w =1
kg of water at T w =15°C,
M e =0.2
kg of eggs at T e =100°C,
and
an
unknown mass M i
of ice at T i =-18°C.
So, the
equation (which is simply energy
conservation) to solve is:
Note that
this is a linear equation for M i
as a function of M w .;
this is shown in the figure. So, 1
kg will about cover the eggs and
about a third of a kilogram of ice
will totally melt when T
reaches 0°C. If you start with more
ice, there will simply be ice still
unmelted in the pot when equilibrium
is reached.
QUESTION:
I am
currently studying for my physics
exam. A student in the group chat
asked us all a question and it got
us stunned. Can you help? Please be
aware that this is NOT a homework
question, we all just share
different opinions on the answer.
Question: A
container with very thick/sturdy
walls is on a frictionless surface.
Inside the container, on the left
side, there is a cannon with
cannonballs. The cannon fires all
its cannonballs against the right
wall, where they fall directly to
the ground upon contact (they do not
bounce back). What is the effect on
the container?
a) The
container stays in place
b) The
container moves to the right
c) The
container moves to the left
d) Not
enough information
I personally
think the answer is A, but a lot of
people are saying C, and others also
say D. I'm lost.
ANSWER:
See the
figure. I assume that the box and
cannonball are rigidly attached and
have a combined mass of M ;
the cannonball has mass m .
Before the cannonball is fired, the
whole system is at rest and so its
linear momentum is zero. Afterwards
the cannon ball is moving (relative
to the ground which is where the
momentum was previously zero). But
the total momentum must still be
zero (conservation of momentum)
because there are no horizontal
external forces on the system. So,
mv-MV =0 or V=mv /M ;
when the cannonball hits the wall
its horizontal linear momentum
becomes zero. There are still no
horizontal external forces so the
motion of the box must also stop.
Clearly the answer is c).
There is
another way you could look the
problem. Since after the the cannon
is fired the cannonball, previously
at rest, now is moving. So the
cannon/box must have exerted a force
F on the
cannonball. But Newton's third law
says that the cannonball exerted an
equal and opposite force -F
on the cannon/box
etc .
QUESTION:
I am a
high school senior who writing
software for the avionics of our
school's model rocket for the TARC
rocketry competition. I have taken
AP mechanics (Calculus based) and
had a difficult time figuring out
the projectile path of a rocket.
After burnout the rocket will coast
to a target apogee (around 800 ft)
at subsonic speeds. The rocket has
onboard an accelerometer (plus
gyro), a really accurate clock, and
an altimeter (with barometer). I was
wondering if there was a way to
predict the exact apogee of the
rocket based soley on the
accelerometer readings and the clock
(while knowing all the constants:
mass, drag coefficient, etc.)? My
team and I have tried several ways
to do this but we get stuck in
dependency loops. Drag is based on
velocity while velocity is based
subsequently on drag. We tried using
energy, momentum, even modified
kinematics (for changing
acceleration), none of which worked.
What we need is a single function
that takes in current vertical
acceleration and the constants and
predicts a delta height which we can
added to the current height to
predict apogee. Also, since air
pressure is part of drag and that
changes based on height according to
a function, it would be nice if we
could put that into the predictive
function. I really don't want to
make this question too long but if I
could add one more layer of
complexity. We are using air brakes
to control the altitude to achieve a
target apogee. We planned to run the
above mentioned predictive function
in a loop and reverse engineering it
to create another function to find
out how much more drag area we would
need to achieve the target altitude
since the airbrakes are radial flaps
that just increase our cross
sectional area.
ANSWER:
First of
all, you have not given me nearly
enough information about what you
are trying to do. Is the time the
rocket is burning part of your
calculation? It is very different
(and harder) than the trajectory
after burnout for several reasons.
Is the trajectory one-dimensional,
i.e . straight up and back
down? Or does the motion of the
rocket also have a horizontal
component? Does the accelerometer
give you the direction of the
acceleration vector? And, if not, it
is not very useful. Do you know the
mass of the rocket before and after
burnout?
All the above
is necessary for me to give you any
guidance. But the way you are
approaching the problem, common
among newcomers to physics, is all
wrong. One of the most important
things to consider when solving a
problem in the real world (not the
ideal models of on-the-blackboard
problems in a physics classroom) is
to determine what is important and
what can be approximated without
serious error. Except in textbook
problems, you should never expect to
be able to get the appropriate
equation in just one step, you need
to make sure you understand things
step by step. You should be starting
out by imagining you are doing a
textbook problem—ignore drag and
ignore the change of mass during the
burn. Then you might put in drag.
Here is a little tip: A fairly good
approximation for air drag D
is D ≈¼Av 2 .
Here A is the area
presented to onrushing air and v
is the speed; the vector
D
must be
opposite the vector v .
The catch is that you must use SI
units here and D will come
out in Newtons. The estimate for D
does not look dimensionally correct;
that is because lots of stuff is
included in that little factor ¼
like the fluid is air, the density
is atmospheric pressure at sea
level, the shape is a generic
sphere, etc . Including
D in your calculations will
tell you if it is actually very
important for your problem.
That's
probably all I should do at this
point. If you answer my questions
about what you are trying to
accomplish, maybe I can give you
some other instructions.
By the way,
if you know the acceleration as a
function of time you should be able
to determine the position and
velocity as functions of time if you
know the initial position and
velocity. It would require numerical
integrations because a will not be
constant.
REPLY:
I am only
simulating the rocket after
burnout. As such, the problem is
more like finding the trajectory
of a cannonball mid-flight.
Like a
cannonball, the projectile will
have velocities in the
horizontal and vertical
direction, however only the
vertical component is needed as
I am trying to predict apogee.
The problem
is that at an arbitrary time
during the ascent of the
cannonball, we will be given
vertical acceleration (drag and
gravity with direction), current
altitude, and time (if that is
needed though it might not be),
and we must determine the apogee
time and altitude.
Constants
like mass (after burnout), cross
sectional area, drag
coefficient, etc. are known.
Drag is
quadratic (v^2) Without drag,
the apogee is simply found with
kinematics (constant
acceleration), but since drag is
a changing force that imparts a
changing acceleration unlike the
constant 9.81 of gravity, no one
on the rocket team could figure
it out.
Also, I have
found other equations online that
include drag and give altitude as a
function of time, but the equation
we need should just give out a
number for max altitude based on the
given values stated above. That's
why we tried using energy formulas
to solve the problem since at the
top there is no kinetic energy, only
potential (again only vertical
components).
ANSWER:
There is
a good reason why you are having so
much trouble: You are high school
students who, at most, have had
introductory differential and
integral calculus. As I will show,
this problem will require
differential equations. And not just
simple linear differential
equations, but coupled second-order
nonlinear differentials. Such
equations can only be solved
numerically, almost never
analytically. I have given a little
thought and have thought of a way
that just might work for you. It
won't be easy. One thing before we
get started: You said "only
the vertical component [of the
velocity] is needed ."
This is not correct because to get
the behavior of the vertical
component you must also know the
horizontal velocity.
One thing
which I am not clear on is what you
are given. It is imperative that you
know the initial velocity, both
magnitude and direction, to solve
this problem. When you say
"we will be
given vertical acceleration" I think
you must mean "we will be given
acceleration" because the
acceleration is not vertical. When
you say "drag and gravity with
direction" I assume that the drag
force, both vertical and horizontal
components are given. The drag force
is usually written
D =-C|v |v ,
so Dx =-C √[vx 2 +vy 2 ]vx
D y =-C √[vx 2 +vy 2 ]vy
From these equations you
can deduce that
v =√(D /C ) and
vy /vx =Dy /Dx =tanθ
where θ= tan-1 (Dy /Dx )
is the angle v makes with
the horizontal. From the initial
drag you can now get the two
components of v ,
vx =√(D /C )cosθ
and vy =√(D /C )sin θ .
So this is how you get the initial
values (t =0) values of the
components of the velocity. I will
choose that the initial values of
x and y are both
zero, i.e. I choose the
origin of my coordinate system to be
at the initial position of the
rocket.
So now we are
ready to do some physics. What's key
in classical mechanics? Newton's
second law, F =ma .
m (d2 r /dt 2 )=-C |v |v -mg 1 y
where 1 y
is the unit vector pointing
vertically upward, m is the
mass, r is
the vector pointing from the origin
to the rocket at time t ,
and g is the acceleration
due to gravity. I realize that
vector calculus is something you
have not yet studied, but it's not
so bad because we just write it in
component form:
m (d2 x /dt 2 )=-C|v |vx =-C √[vx 2 +vy 2 ]vx
m (d2 y/dt 2 )=-C|v |v y -mg=-C √[vx 2 +vy 2 ]v y -mg.
These are second-order (second
derivative), non-linear (square
root), coupled (vx
and vy both
appear in both equations) equations.
But we can make them much more
tractable by noting that (d2 x /dt 2 )=(dvx /dt )
and (d2 y /dt 2 )=(dv y /dt ).
Finally
we have
(dvx /dt )=-β √[vx 2 +vy 2 ]vx
and
(dv y /dt )=-β √[vx 2 +vy 2 ]v y -g
where β=C/m . Now we can't
solve these analytically but we can
do it numerically (that's where you
come in!). This will just involve
arithmetic. Δvx ={-β √[vx 2 +vy 2 ]vx }Δt
and Δvy ={-β √[vx 2 +vy 2 ]vx -g }Δt.
So here is your computer
programming problem. You know β ,
g , vx ,
and vy at t= 0,
they all are just numbers. Choose
some Δt , say Δt =1
s and then you can calculate the
changes in the velocity components.
Now you know the (approximate)
values of the component velocities
at t =1 s. Now you calculate
with those and get the values of the
velocities at t =2 s.
Continue until you find the time
when vy ≈0; going
past this t vy
will become negative. You will
probably need to try several values
of deltat until it is small enough
that the final answer doesn't change
(you are, after all, simulating what
you would get with infinitesimal Δt).
After you find the total time
to the top, you still haven't
answered where it is. What you need
to do is to integrate into your
program calculation and tabulation
of Δx=vx Δt
and Δy=vy Δt
at each interval, and calculate
running sums. The final sum of Δy
is your answer.
I know that
this is a lot for a high schooler to
digest. But I have tried to simplify
as much as I could. As I warned you
at the beginning, when you have air
drag to contend with, you have a
much more complicated problem than
with constant forces. If you are
able to pull it off I would love to
see your results.
ADDED
THOUGHT:
To check
that I have not made an algebra
error somewhere I have written a
PYTHON code to do the calculations I
suggested above. I randomly chose
reasonable boundary conditions,
β =0.001, v x (t =0)=100
m/s, v y (t =0)=200
m/s, g =9.8, and Δt =0.25
s.
Shown are the velocity and the
position components as functions of
time and the path of the rocket,
y as a function of x .
QUESTION:
We have
read for years that the universe is
composed of certain percentages of
visible matter, dark matter, and
dark energy. I can understand that
there are ways of reasonably
estimating the amounts of visible
and dark matter. They are described
for us in published articles. How
does anybody estimate the amount of
dark energy? And what is it anyway?
Is dark energy expected to have all
the characteristics types that
regular energy has - kinetic,
thermal, etc.? All of the articles
that I have seen simply present a
percentage associated with dark
energy. There don't seem even to be
some typical characteristics of dark
energy that would allow us in the
public to form a concept of what it
is. Falling back on the Classical
Physics model, dark energy has to be
the ability to do work on dark
matter, if that helps! Regardless of
what dark energy actually, is one
still wonders: how is it estimated?
ANSWER:
Site
ground rules clearly state that I do
not do
astronomy/astrophysics/cosmology. I
can tell you though that it is not
clearly understood what either dark
matter or dark energy actually are.
FOLLOWUP
QUESTION:
But as a last
thought, they tell us that dark
matter can be evidenced by its
observed effect on real matter. And
then they quote actual percentage
estimates for the amounts of dark
matter and energy. And yet dark
energy, I think, has not even been
detected. There must be a process
used to arrive at these numbers.
That's what I am really after. Can
you direct me to anyone or any
organization that I can communicate
with to find out just how it is
done? My thought is that, if I can
understand the process, I can more
clearly Understand what "they" think
these things are. Maybe not.
ANSWER:
Dark
matter is thought by most
astrophysicists to be some kind of
particle which interacts only via
gravity. It is very hard to
"observe" something if you cannot
interact with it using
electromagnetism. There are numerous
anomalies in the universe which seem
to not be described by our current
"best" theory of gravity, general
relativity. You may make a model
of hard-to-detect particles with
mass but which only interact with
the rest of the universe via
gravity, but if that model works it
does not mean that you have
"detected" dark matter, you have
only fitted the data, not
necessarily one which tells you what
dark matter is ; at this
level it is empiricism. It may be
that dark matter is not stuff, but
an indication that we don't
understand gravity as well as we
think we do.
Dark energy
is a different kind of thing. You
say that it "…has
not even been detected…" That is not
correct, it has been "detected" just
as surely as dark matter has. The
evidence for it is that very distant
galaxies are observed to be not just
moving away from us but
accelerating. In other words you can
assume that there must be some
universal repulsive force pushing
the universe apart. In my opinion,
dark energy is in just as detected
as dark matter is.
There is an
interesting back story about dark
energy. Circa 1918, when
Einstein was putting the finishing
touches on his theory of general
relativity, it had not yet been
discovered that the universe is
actually expanding; it was assumed
to be static. That presents a big
problem since gravity is a
long-range attractive force which
should have been causing the
universe to be collapsing. So he
added a term to general relativity
to hold everything in place and it
became called the cosmoligical
constant λ . Much later in
his life, when it was discovered
that the universe is not static, he
said that λ was his
"biggest blunder". In 1998 when
acceleration of distant galaxies was
observed, new life was given to
λ ! If you are interested in
delving into this more deeply, check
out this
link.
QUESTION:
I was
wondering if a feather and a bowling
ball actually pull towards the earth
at the same rate? Why would the
gravitational fields produced by the
feather and the bowling ball not
increase the rate of their
individual attraction towards the
earth?
ANSWER:
First we
need to specify that this notion
requires that there be no forces
(like air drag in the real world)
other than gravity acting, the earth
must be assumed to be enormously
more massive than the feather and
bowling ball (which is true), and
the gravitational force which the
earth exerts on the objects is
uniform (which is true only close to
the surface of the earth). Also, you
seem to be a bit muddled as to what
is going on. The reason that the two
masses accelerate is that each feels
a force due to the gravitational
field of the earth, it has nothing
to do with the gravitational fields
of the objects themselves. You seem
to be thinking that the bowling ball
feels a bigger force and that is
true; the force anything feels
(which is called the weight of that
thing) is proportional to (depends
on) its mass. But the effectiveness
of that force, what acceleration
(the rate at which its speed will
change while falling) it falls with
is inversely proportional to its
mass. So, if the mass of the ball is
1000 times bigger than the feather's
mass, the force on it will be 1000
times bigger. But, the more massive
an object is, the more force
required to give it a certain
acceleration is. It just so happens
(because of Newton's second law that
the force necessary is proportional
to the mass. Therefore although the
ball has 1000 times the mass, it
takes 1000 times as much force to
accelerate it as it takes to
accelerate the feather. The
acceleration is g =9.8 m/s2 .
If you want a more mathematical
discussion, see an
earlier answer .
QUESTION:
One of
the issues YouTube physicists
discuss regarding interstellar
travel is that the high speeds we
would achieve would render the
spaceship more vulnerable to
constant bombardment by particles,
gases, and dust, requiring a thicker
hull in the direction of travel.
Assuming interstellar travel is
possible with current or near-future
tech (not a given), is it true that
more particles and gases would
impact in the opposite direction of
travel? That would seem to assume
that most particles are more or less
at rest in the frame of reference we
are coming from with Earth. Wouldn't
they all be going at random
velocities up to near the speed of
light relative to us? Within the
solar system, are particles mostly
at rest relative to Earth's frame of
reference? Within the
gravitationally-bound Local Group?
ANSWER:
Unfortunately, the space between
planets, stars galaxies are not true
vacuums as we often think of them.
So, inevitably, atoms and molecules
will be present in varying
densities, sometimes just moving
around in relative vacuum, sometimes
congregated in clouds. And you are
right, they will be moving in random
directions with a distribution of
speeds, but the speeds are all very
small compared to the speed of
light, c . But a ship
traveling to distant stars would
have to have speeds which are not so
tiny compared to c . And to
someone on that ship, all the
particles will be moving mainly at
speeds close to the speed which the
ship has. When you say "mostly at
rest" you do not define what that
means. What is true is that their
speeds are very slow compared to c;
if that's what you mean by "mostly
at rest", then yes most particles
which you encounter will end up
coming toward you with a speed very
close to the speed you are
traveling.
FOLLOWUP
QUESTION:
Thank you for
answering my question!! I have
refined it to clarify the point you
brought up.
We are
measuring the velocity of the
spacecraft relative to Earth's frame
of reference. Therefore, we are
measuring the velocities of the
particles it might encounter from
the same frame of reference -
Earth's. You can't compare any
particular velocity to the speed of
light without a frame of reference.
You must have an observer with its
own frame of reference to measure
the speed. Why should we assume that
particles outside the Solar System
or Local Group travel at very low
speeds compared to the speed of
light from our frame of reference?
Shouldn't we see the same number of
high-speed particles bombard the
ship from all directions, regardless
of its velocity relative to Earth?
Does the idea that the spacecraft
will encounter more particles in the
direction of relativistic travel
rely on the fact that all particles
in the Local Group are
gravitationally bound together?
ANSWER:
My bad! I
should have specified my reference
frames. Let's call the earth our
"rest" frame. First some numbers:
Typical
atom/molecule densities most
places in our galaxy is 10-100
particles/cm3
Typical
atom/molecule densities in
intergalactic space is 1
particle/m3
Typical
temperatures of most places in
our galaxy is 10-100 K
Typical
RMS speed of molecules is slow,
e.g. , CO2 at
10 K is about 300 m/s
So if we
say that probably particles with
speed 10 v RMS
are the fastest with any
appreciable number, those have
speeds 3000 m/s=10-5 c .
Since the
biggest speeds relative to the earth
are so tiny compared to the speed of
light, they look like they might as
well all have been at rest compared
with the motion of the ship.
Therefore, on the ship with some
velocity U ,
every
atom or molecule will be seen moving
with a velocity very close to
-U .
Suppose that
you are driving in a forest at 50
mph. Every tree from your frame of
reference is moving backwards at 50
mph, not just trees in front of you.
QUESTION:
Since
the discovery of the Higgs Boson,
which is said to be what makes
matter essentially makes things be
physical. Then wouldn't it make
sense that there is indeed a
graviton? In where the particle is
in a wave function until check and
collapsed into a particle? Not
unlike the double slit. Couldn't
this be the case? And it is my
opinion that this could fit nicely
into an current theory.
ANSWER:
I don't
understand hows Higgs or double
slits have anything to do with
whether "…there is indeed a
graviton…". I will assume that the
main issue is you want to know is
whether "…there is indeed a
graviton…". As you may know (see the
next question) general relativity is
generally depicted as a geometric
model, deformation of spacetime by
mass. So gravity is not a force,
merely geometry? If that is the
case, why seek a quantum theory of
gravity where the quanta (gravitons)
would be "messengers of the force"
when there is no force, only
geometry? But a few years ago I came
across a short
essay which made the whole thing
clear to me. A theory does not have
to have only one framework of
characterizing it. For example, when
quantum mechanics was in its
infancy, two competing mathematical
frameworks were used, both of which
seemed to come to the same result
when calculating: Matrix mechanics
was formulated by Heisenberg, Born,
and Jordan; differential equation
formulation of quantum mechanics was
introduced by Schrodinger. The two
were eventually shown to be
identical. Similarly general
relativity has the properties of a
field theory and can be interpreted
as having forces and being
quantized. Hence, there should be a
theory of quantum gravity. If you
want to read more see my
earlier answer and be sure to
look at the
essay linked there.
QUESTION:
Hi. I’ve
been pondering gravity lately. Why
is it that -- although Einstein's
general relativity best explains
what we call "gravity"-- one still
sees statements such as "all masses
attract each other – you and your
pet, the earth and the moon . . ."
etc., etc. What magical "attraction"
are they talking about? Also,
could you recommend a good
illustration of what actually
happens when an object near the
earth "falls"?
ANSWER:
The
theory of general relativity (GR) is
quite complicated mathematically. To
understand a complicated physical
theory requires that we have a
qualitative explanation of some
effects predicted to visualize. GR
is a theory which uses advanced
geometry formalism, a
four-dimensional spacetime (time
being the fourth dimension). It
therefore becomes a theory we think
of as a geometrical theory and
envision massive objects to deform
the spacetime around them resulting
in attraction. But, there's a
problem—since we live in a
3-dimensional world we really can't
visual a 4-dimensional world. So
what is usually done is to imagine a
2-dimensional plane which, if we put
a bowling ball in it, gets deformed.
If there is a marble nearby it will
roll toward the bowling ball; I
often refer to this as the
trampoline model and it is a cartoon
not to be taken too seriously but to
provide an example of an object
deforming some space around it. You
can also give the marble a little
shove and it will orbit the bowling
ball as shown in the figure. The
marble also deforms the space around
it but since it has so little mass
compared to the bowling ball, it is
not apparent in the figure.
QUESTION:
Recently
I’ve got interested in one question.
Lets assume we have 2 balls with
same mass in space on some distance
from each other (no other objects
around). At the initial moment of
time they are staying still
(velocities = 0). Then, due to
gravitational attraction, they start
moving toward each other. At some
moment they collide and collision is
elastic — so they move away from
each other, slow down and then again
start moving toward each other (then
collide ets.) The question is — will
they bounce forever (because of
conservation of energy) or they
eventually, like, stick to each
other?
ANSWER:
The
problem with your question is that
you ask for an answer in an ideal
situation, perfectly elastic
collisions and perfectly empty
space. Under those conditions, the
two balls would bounce forever. The
fact is, though, that no macroscopic
balls can collide perfectly
elastically and no vacuum is
perfect. So in the universe we live
in, the balls would lose a little
energy every time they collided and
quickly stop, "…stick[ing]
to each other…". And even if you had
perfectly elastic collisions, actual
"empty space" (intergalactic space)
contains about one molecule per
cubic meter; it might take eons, but
eventually the balls will collide
with those molecules giving some of
their energy to them and eventually
sticking together. And don't forget,
there are lots of photons zooming
around which could add or subtract
energy when they hit the balls.
QUESTION:
A while
back I was reading an article about
the electromagnetic spectrum, the
visible light spectrum specifically.
And a question raced through my
mind. If I understand correctly the
colors we perceive are based on
reflective properties of objects in
our environment. Certain reflective
properties reflect different
wavelengths of light and we perceive
them as colors. My question is in
the absence of all light does
anything truly have a color? And if
so what do you think that looks
like? An infrared photo is the
closest that I can imagine.
ANSWER:
If a tree
falls in the forest and there is
nobody nearby to hear it, does it
make any sound? Your question is
similar—both are about semantics,
not physics. If you say that sound
is your perception of it, the tree
makes no sound if there is nobody to
hear it; on the other hand if you
say sound is the presence of
compression waves traveling through
the air, there is sound. Color is
trickier, though, because the color
you perceive depends on how it is
illuminated. We usually think of
white light as a distribution of all
the wavelengths of sunlight. So just
saying something is red is a grossly
undetermined description because
something red in one illumination
may look pink in another. So physics
avoids this confusion and simply
uses the word color in a qualitative
sense, just like you might describe
something as warm to denote
temperature. So if you want to know
what "color" something is you
specify the distribution of
wavelengths emitted from an object
when it is illuminated by a
different distribution of
wavelengths.
QUESTION:
I was
trying to bounce my Walmart ball at
the ground and have it bounce off
the ground, hit the ceiling, bounce
off the ground and then hit the
ceiling again. I noticed that no
matter how hard I threw, it would
never hit the ceiling twice. I
assume it is impossible for a
physics reason and would like to
know specifically what. The ceiling
is about 8 ft high, ball is about 42
inches around.
ANSWER:
The
"physics reason" is that your arm is
incapable of giving the ball enough
energy. Each time the ball has a
collision with ceiling or floor it
loses a fraction f of its
energy, so if its incoming energy is
K , its outgoing energy is
K (1-f ); as it
travels from the floor to the
ceiling it loses energy V=mgh
where m is the mass of the
ball, g is the acceleration
due to gravity, and h is
the distance the center of the ball
travels; as it travels from the
ceiling to the floor it gains energy
V . What I did is to
calculate the energy step-by-step to
find
the
minimum initial energy K 0
needed for the final kinetic energy
to be zero, just as it reaches the
ceiling for the second time. Then I
solved the equation I got for K 0 .
The result was
K 0 =V (F 2 -F +1)/F 3
where F =1-f , the
fraction of energy retained in a
collision.
The
energy is just the kinetic energy,
K 0 =½mv 2 =mgh (F 2 -F +1)/F 3
so v =√[2gh (F 2 -F +1)/F 3 ].
So let's look
at your case, the radius of the ball
is about 6" so h is about
7'=2.1 m, g is 9.8 m/s2 ,
and I will guess that F is
about 0.5 which means half of the
energy is lost in each collision (I
dropped a similar ball and it
bounced back about halfway from
where I dropped it). Therefore,
v =15.7 m/s=35.2 mph. I doubt
that you could give it that
velocity.
QUESTION:
I'm
doing my level best to finish my
first speculative fiction novel, and
this is a question to which I'm
unable to have anywhere close to
100% confidence in my answer. I'm
hoping your much more vast breadth
of knowledge might help give me a
bit more certainty with it; even if
you have to do some educated
guessing - which is more than I'd be
able to do (though I've shared my
guess below). So here goes: I would
like to have as close to an accurate
sense of how water would move on
other worlds; specifically, were all
atmospheric conditions identical to
Earth's, how would water (and most
other liquids then) move on the Moon
("The Expanse" showed liquids moving
much more slowly on the Moon) and on
Mars? My guess is, if they were
right - I assume Astronomer/producer
Naren Shankar has an pretty solid
sense of it - and atmospherics are
essentially the same, the biggest
factor is the strength of the
gravity; more than the speed of
rotation (but this is a factor I'm
uncertain about). Stronger gravity
will make liquids move more quickly,
I believe, but if they were right on
that show, then twice as fast as on
the Moon - or if rotation speed is a
bigger factor than I'm thinking,
that's something I'll have to
educate myself about.
ANSWER:
The speed
v in deep water is v deep =√(gL /2π )
where L is the wavelength
of the wave and g is
gravitational acceleration; 'deep'
means h ≥½L . So the
speed is proportional to the square
root of g and to the square
root of L . For example, a
water wave on the moon would have a
speed of about v moon =√(1.6/9.8)v earth =0.4v earth .
On Mars, v Mars =√(3.7/9.8)v Mars =0.61v earth .
For shallow water, h ≤0.04L ,
the speed is approximately v shallow =√(gh );
here the speed is proportional to
root h rather than root
L . There is even an approximate
expression for the intermediate
depths, v inter =v deep tanh(kh )
where k =2π /L .
This is probably more than you need
to know, but if you want to see the
whole reference which I used, go
here .
QUESTION:
I
understand that time slows down for
objects moving at relativistic
speeds. However, I don't understand
why the slow-down in time directly
affects things. Why are biological
reactions slowed down (so I age more
slowly). Or why are chemical or
nuclear reactions slowed down? Even
though they call time the 'fourth
dimension', it seems to have a much
more direct effect of things than
space does. If space where increased
or decreased by 50% in extent, I
wouldn’t become 50% bigger or
smaller. If physical objects were
directly affected by the growth or
reduction of space dimensions, how
would you ever be able to measure
that change?
ANSWER:
You
misunderstand time dilation. If you
are moving with some large speed
relative to someone else, your clock
runs at some rate which is totally
the same as you would at
any speed. You do not see that clock
running at a different rate because
you were moving relative to someone
else. If your ship had no way to
look outside, you would not even
know you were moving. What is
different is the rate which you
clock runs is different than the
clock which is at rest relative to
you runs. You should read my
description of the
twin paradox .
QUESTION:
So I am
having problem in understanding if
the acceleration must always be
constant when we think of Free Fall.
For example, imagine if I were about
70,000km above Earth’s surface and
the only object in my vicinity is
Earth, then I’d only feel
gravitational force of earth.
Suppose I am falling towards Earth,
then by definition what I experience
is free fall. But when I get closer
to Earth, say when I am 1,000km
above the surface, the acceleration
I’d feel would not be the same as
what I felt when I was about
70,000km above the surface. Having
said that, can I conclude that the
only reason we experience constant
acceleration when we experience free
fall on Earth is because the height
for the motion is significantly less
than the radius of Earth and
therefore, we can ignore the minute
changes in gravitational
acceleration?
ANSWER:
The
gravitational force F on a
mass m at some distance
r from the center of a
spherically symmetric sphere of
radius R and mass M
is F=MmG /r 2
where G is Newton's
universal gravitational constant.
Because of Newton's second law,
a=F /m , so a=MG /r 2 .
If you set M and R
to be the mass and radius of the
earth you will find that a
is about 9.8 m/s2 . That
is the only r which has
this as the value of a ; in
other words, the acceleration is
never uniform. But, as is often
the case in science, a good
approximation can yield perfectly
adequate approximate results
provided that you understand the
limitations. It is clear from your
question that you already understand
that very well. I will give you a
quantitative way of estimating how
high h in altitude you can
go before the approximate
acceleration differs from the
ground-level acceleration:
First,
a (r=R )=g =MG /R 2 ,
a (r=R+h )=g'=MG /(R+h )2
Next,
write
(R+h )2 =R 2 [1+(h /R )2 ]
so that we can write g'=g /[1+(h /R )2 ]
or g /g' =1+(h /R )2
Suppose
we want there to be only a 1%
error at some h ; what
is h ?
(g-g' )/g =g (1-g /g' )=0.01g =g (h /R )2
so h =√(0.01R 2 )=0.1R
QUESTION:
If the
Laws of Thermodynamics and the
Conservation of Matter state thate
neither energy nor mass can be
created nor destroyed, why do
theoretical physicists fixate on the
big bang as the creation of the
universe? To me it seems logical
that both energy and mass (being
interchangeable) are eternal, and
that the big bang that caused the
present universe may just be the
latest of the likely cycle of
eternal big bangs. What do you
think, is it logical?
ANSWER:
There is
no such thing as "conservation of
matter" because matter can be
created or destroyed. The total
amount of energy in the universe
cannot be changed although the
amount of mass may change. However,
I see no reason why the "eternal"
amount of energy in our universe
should preclude "fixating" on the
big bang.
QUESTION:
But
energy cannot exist without matter
and matter cannot exist without
energy. As both would be stagnant in
the absence of the other. The laws
state that in an isolated system
neither mass nor energy can be
created or destroyed. Mass is a body
of matter of indefinite shape or
size. Therefore mass is matter and
cannot be created or destroyed. How
then, do you validate your
proposition that it can be?
ANSWER:
This is
utter nonsense. "The laws" state
that in an isolated system the total
energy must remain constant. Mass is
just a form of energy, E=mc 2
. You are not alone in believing
that conservation of mass is a law
of physics; I often get questions
based on this assumption. So. where
did this "law" come from? Modern
chemistry was developed about 400
years ago. Experiments showed that
if you measured all the mass which
contributed to a chemical reaction
and then measured all the mass after
the reaction, the two, within the
accuracy of measurement, would be
equal. The catch is that the
accuracy of the measurement is too
poor to say that the two are
precisely equal. When special
relativity was developed, it became
clear that mass could be converted
into energy because E=mc 2 .
In an exotheric reaction, energy is
released in the form of heat and the
origin of that energy is a tiny
decrease in the mass. Indeed, even
with the most sensitive instruments
it is virtually impossible to
measure this; chemistry is a very
inefficient source of energy. But if
you look at nuclear reactions, the
mass change is easy to measure;
e.g ., the mass of a helium
nucleus (two protons and two
newtrons) is about 3% lighter than
the summed mass of two protons and
two newtrons. Stars, like the sun,
are using nuclear reactions to
release energy from mass. If the sun
were burning using chemistry, it
would have been totally reduced to
ashes millions of years ago.
QUESTION:
I was
wondering how the oceans can absorb
CO2 from the atmosphere if they have
achieved equilibrium.
ANSWER:
Lot's of
reasons. First, the CO2
doesn't just swim around but
iteracts chemically so that the
water dynamically reduces levels
allowing more CO2 to
replace that decrease. If the amount
of CO2 in the atmosphere
is increasing which causes the
equilibrium to be undone whether the
CO2 is decreasing or not.
So the real equilibrium is dynamic,
not static. By the way, the
chemistry causes the ocean to become
more acidic, not desireable.
QUESTION:
I have
come across this paper written by a
person called John Mandlbaur. He
claims:
"My papers are
rejected because they come to a
conclusion which the editor doesn’t
believe. That is what rejected
without review means. Numerous
physicists have described my maths
as perfect and nobody can defeat
it."
Now I do not
believe this because although I am
no physicist, I know physics well
enough that papers are not rejected
without good reason so I am sure his
is rejected because the calculation
and/or reasoning is fatally flawed
but being no physicist myself I am
not qualified to comment on the
paper. If however you identified the
relevant flaws in straightforward
English, I could post your reply on
Quora and hopefully prevent others
from being taken in by these claims
of Mr Mandlbaur's. If this is not
for you, but you can recommend
someone else to explain why the
paper is refuted in plain English
please let me know.
ANSWER:
I
interacted with this fellow
about 7 years ago. We had a very
lengthy back-and-forth discussion of
his "ideas" which eventually became
so outrageous that I relegated
him to the
"Off-the-Wall" Hall of Fame ". I
don't want to call names, but there
has never been a questioner more
worthy of off-the-wall status than
him. It is very sad that he has held
on to these delusions for such a
long time. I think it was Bill
Murray who said "It’s hard to win an
argument with a smart person, but
it’s damn near impossible to win an
argument with a stupid person." I am
sure that if you go over these
ramblings you will have plenty of
examples to convince yourself that
Mr Mandlbaur is
a crackpot.
QUESTION:
I have
come across this paper written by a
person called John Mandlbaur. He
claims:
"My papers are
rejected because they come to a
conclusion which the editor doesn’t
believe. That is what rejected
without review means. Numerous
physicists have described my maths
as perfect and nobody can defeat it.
Now I do not believe this because
although I am no physicist, I know
physics well enough that papers are
not rejected without good reason so
I am sure his is rejected because
the calculation and/or reasoning is
fatally flawed but being no
physicist myself I am not qualified
to comment on the paper. If however
you identified the relevant flaws in
straightforward English, I could
post your reply on Quora and
hopefully prevent others from being
taken in by these claims of Mr
Mandlbaur's. If this is not for you,
but you can recommend someone else
to explain why the paper is refuted
in plain English please let me
know."
ANSWER:
I
interacted with this fellow
about 7 years ago. We had a very
lengthy back-and-forth discussion of
his "ideas" which eventually became
so outrageous that I relegated
him to the
"Off-the-Wall" Hall of Fame . I
don't want to call names, but there
has never been a questioner more
worthy of off-the-wall status than
him. It is very sad that he has held
on to these delusions for such a
long time. I think it was Bill
Murray who said "It’s hard to win an
argument with a smart person, but
it’s damn near impossible to win an
argument with a stupid person."
QUESTION:
I am
writing a science fiction story, and
I’d like the science to be accurate.
So: if a space ship starts from
Earth and steadily accelerates at 2
G’s, how far will it be from Each in
three months, and how fast will it
be going? Thank you so much; what
I’m writing is a love story
intertwined with the difficulties of
interstellar commerce.
ANSWER:
Before
you do anything you should read the
four previous
answers which you can find in
the faq page. If you don't care to
get into the details you can just go
to
this link which will let you
know how I did the calculations for
you. You first need to understand
that acceleration is not a very
useful quantity in physics if
velocities are comparable to light
speed; this is discussed in the
previous answers I refered to above.
Since you are interested in high
speeds, we need to first determine
whether classical Newtonian physics
can be used or whether we need to
use special relativity. We first
need to specify who is measuring the
acceleration since it is not the
same as seen by everyone with high
relative speeds; I assume that you
are interested in where the ship is
and how fast it is going after three
months. The figures show
calculations I have done assuming
g =10 m/s2 , for
both relativistic (red) and
Newtonian (black) mechanics, and an
acceleration observed from the rest
frame of 2g . and
essentially velocity as a function
of time. The first figure calculates
up to about t= 23 months,
the second to 3 months. Note that
the first calculation has the
relativistic calculation approaches
c at large t
whereas the Newtonian calculation
increases linearly forever, already
at about twice light speed at about
one year. But, as shown in the
second figure, the two calculations
are approximately equal at 3 months.
Therefore at 3 months you could say
that the speed of the ship is about
half of light speed and the distance
traveled was about d =½at 2
=10x(7.78x106 )2 =6x1014
m=0.06 light years. It would be much
more complicated to calculate the
distance relativistically.
QUESTION:
My
question is about spinning black
holes. Or rather spinning
singularities. Like singularities
are one dimensional objects right? A
point of infinite density. Anyway.
don't you need like...another
dimension to be capable of spinning?
Like what axis does the point spin
around? How can you rotate when
there is no geometry? I Thought it
was a point. How does a point
rotate? It wouldn't make sense
though. The thing would suddenly
stop spinning because there was no
more geometry to rotate. Anyway,
everytime I try to think about it I
sorta reach this block in my head.
ANSWER:
Not one
dimension, zero dimensions. Still
your questions are pertinent. The
first thing you should accept is
that we do not know what the physics
of a black hole is. The laws of
physics are not known inside the
Schwarzschild radius. But reasonable
calculations which can be done seem
to lead to a true mathematical
singularity. I feel that most
physicists are uncomfortable with
the literal idea of infinities. That
said, there is no reason why a point
particle cannot have angular
momentum. When black holes initially
form from the gravitational collapse
of a dying star and the star
originally had angular momentum,
that property will be conserved.
From that point of view, one would
expect just about every black hole
to be "spinning". You are thinking
classically, but most elementary
particles have intrinsic angular
momentum (spin) but if you try
to interpret it as the physical
spinning of some mass distribution
about some axis you will fail.
Electrons are thought to be point
particles and they certainly have
spin.
QUESTION:
I am
trying to figure out how quickly
(approz) a tangential velocity (I
think) something would have to have,
rotating around the earth at an
altitude of about 400kms, to have a
centripetal force of 1g ie 9.82
newtons. I think that's the right
terminology? Here's my thinking:
I think
escape velocity at that distance
is (very) roughly 27,360kph?
So if
you're going at just or just
under that speed you're in
constant freefall round the
earth, ie experiencing zero
gravity, in a vertically
constant orbit. (First hurdle: I
don't even know if that's
correct!)
FYI, I'm
imagining a hypothetical band
looping entirely around the
earth at ~400kms altitude, for
example, creating its own
centripetal force.
If you
stood on the inside of that
band, head towards the Earth,
and this is where my thinking
gets v v doubtful, would you
then have to spin whatever the
whole artefact (I think it comes
out at something like a
tangential velocity of 29,366kph
to create a 1g centripetal
force?) on top of the originally
calculated escape velocity in
order to create 1g's reactionary
force?
So, is the
end tangential speed the band
would need to rotate approx
56,726kph?
ANSWER:
I am
sorry to tell you that most of the
things you say are nonsense. Let me
just tell you how things are rather
than picking your question apart.
First, qualitatively: A circular
orbit of radius r (r
being the distance from the center
of the earth) will have a particular
velocity associated with it; you
seem to think that you can choose
the velocity you would like to have
in that orbit. The gravitational
force on any orbiting object gets
smaller the farther away from the
center of the earth you are; as you
know, the gravitational force on an
object of mass m at r=RE
is
F (RE )=9.82m
where
RE =6.37x106
m is the radius of the earth. So the
acceleration is g (RE )=9.82
m/s2 .
But, in
general g (r )=ME G /r 2
where G= 6.67x10-11
N·m/kg2 is Newton's
universal gravitational constant and
ME = 6x1024
kg. So now you can see that every
orbit is in free fall except the
acceleration of that fall is
dependent on the radius of the orbit
and is only approximately equal to
what you think of as g at
near-earth orbits. We can also
calculate the speed at any orbital
radius r from Newton's
second law
F=mg (r )=mv 2 /r =m ME G /r 2 .
So, solving, v (r )=√(ME G /r ).
You are
interested in the altitude h =4x105
m so r =RE +h =6.41x106
m. Doing the arithmetic, g (r )=9.74
m/s2 and v (r )=7.9x103
m/s=28,440 km/hr.
ADDED
THOUGHT:
Rereading
your question it appears that you
might want to be making "artificial
gravity" like the big donut-shaped
space ships which you see sometimes
in sci-fi movies like 2001 A
Space Odyssey . But I don't know
why you would want to do it around
the earth where there is already
gravity present. If you are
interested in rotating space ships
to create the appearance of gravity
because of the centrifugal force, I
have answered questions along those
lines in the past. Find links on the
faq page .
QUESTION:
I am
trying to figure out how quickly
(approz) a tangential velocity (I
think) something would have to have,
rotating around the earth at an
altitude of about 400kms, to have a
centripetal force of 1g ie 9.82
newtons. I think that's the right
terminology? Here's my thinking:
I think
escape velocity at that distance
is (very) roughly 27,360kph?
So if
you're going at just or just
under that speed you're in
constant freefall round the
earth, ie experiencing zero
gravity, in a vertically
constant orbit. (First hurdle: I
don't even know if that's
correct!)
FYI, I'm
imagining a hypothetical band
looping entirely around the
earth at ~400kms altitude, for
example, creating its own
centripetal force.
If you
stood on the inside of that
band, head towards the Earth,
and this is where my thinking
gets v v doubtful, would you
then have to spin whatever the
whole artefact (I think it comes
out at something like a
tangential velocity of 29,366kph
to create a 1g centripetal
force?) on top of the originally
calculated escape velocity in
order to create 1g's reactionary
force?
So, is the
end tangential speed the band
would need to rotate approx
56,726kph?
ANSWER:
I am
sorry to tell you that most of the
things you say are nonsense. Let me
just tell you how things are rather
than picking your question apart.
First, qualitatively: A circular
orbit of radius r (r
being the distance from the center
of the earth) will have a particular
velocity associated with it; you
seem to think that you can choose
the velocity you would like to have
in that orbit. The gravitational
force on any orbiting object gets
smaller the farther away from the
center of the earth you are; as you
know, the gravitational force on an
object of mass m at r=RE
is
F (RE )=9.82m
where
RE =6.37x106
m is the radius of the earth. So the
acceleration is g (RE )=9.82
m/s2 .
But, in
general g (r )=ME G /r 2
where G= 6.67x10-11
N·m/kg2 is Newton's
universal gravitational constant and
ME = 6x1024
kg. So now you can see that every
orbit is in free fall except the
acceleration of that fall is
dependent on the radius of the orbit
and is only approximately equal to
what you think of as g at
near-earth orbits. We can also
calculate the speed at any orbital
radius r from Newton's
second law
F=mg (r )=mv 2 /r =m ME G /r 2 .
So, solving, v (r )=√(ME G /r ).
You are
interested in the altitude h =4x105
m so r =RE +h =6.41x106
m. Doing the arithmetic, g (r )=9.74
m/s2 and v (r )=7.9x103
m/s=28,440 km/hr.
ADDED
THOUGHT:
Rereading
your question it appears that you
might want to be making "artificial
gravity" like the big donut-shaped
space ships which you see sometimes
in sci-fi movies like 2001 A
Space Odyssey . But I don't know
why you would want to do it around
the earth where there is already
gravity present. If you are
interested in rotating space ships
to create the appearance of gravity
because of the centrifugal force, I
have answered questions along those
lines in the past. Find links on the
faq page .
QUESTION:
I
suppose this is an off the wall
question, but it is quite practical,
and I’m not sure where to ask it. A
web search turns up nothing of
interest. I’ve convinced myself that
my coffee cup is interfering with
the 2.4GHz signal between my mouse
and its receiver, which is plugged
into the back of my display. The
spatial orientation of the three
objects is not ideal, but my desk
setup is a bit limited, basically
thus:
2.4GHz
wireless mouse on pull-out
keyboard tray, mouse on the
right.
My ceramic
coffee mug on the surface of the
desk, just above and beyond the
mouse, also on the right.
My display
is just above and beyond that on
the desk, with the mouse
receiver plugged into a USB port
in the middle of the back of the
display.
Ordinarily,
these three things tend
unconsciously toward an unfortunate
syzygy*. I suspect the coffee cup is
interfering with the signal, causing
severe mouse lag. So far
unexceptional. I don’t see why the
ceramic mug or its mostly water
contents might not be reflecting the
signal. But there doesn’t seem to be
any interference when the mug is
full. Only after drinking half or
more do I notice the lag. If I move
the mug way over to the left, that
seems to eliminate the lag. So my
question is, does the water level in
the mug change the overall resonant
frequency of the mug such that it
can interfere with the signal at
some levels but not others? Is it
like filling a jug to different
levels to get different tones when
you blow across the opening? And
considering that microwave ovens
work on a similar frequency by
heating water, would water be an
especially problematic interloper at
2.4GHz?
ANSWER:
Interference and blockage of
electromagnetic waves are tricky to
understand and track down. Like
sometimes when I am driving and come
to a stop there will be a specific
spot where a local radio station
will suddenly almost be totally
blocked. All the things you have
tried are reasonable: I salute you
because physics is, at its root, an
experimental science. If you could
tolerate moving your cup to the left
side, that is likely your best
solution. The 2.4 GHz seems like a
likely culprit here, particularly
since there seems to be negligible
blockage once the water is removed.
Cups of different construction would
be useful to look at, e.g. ,
a metal cup with and without water.
I doubt that it is anything to do
with interference like the blown
over bottle because sound waves are
of the same order-of-magnitude
wavelength as the resonating object
whereas the GHz waves are nowhere
close to the size of the cup. Good
luck!
*If you, are puzzled, as I was, by
the funny word
syzygy, it means when three or more
objects line up as in eclipses for
example.
QUESTION:
Sir,My
doubt is in POTENTIAL ENERGY .I am
really struggling in understanding
this topic .please help me out.Sir
my question is that -"is potential
energy just a term to make sums look
easier?" Sir, taking an example - if
we throw a ball with v velocity
perpendicularly upward then at the
highest point the velocity becomes
zero therefore the kinetic energy
becomes zero but at this point we
say that the energy has been
transferred into potential energy
but acutually where did the energy
go ? And thus can we say that we
defined potential energy so that our
famous rule does not gets violated
i.e. "energy can neither be created
or destroyed it can only be
transferred from one form to another
" is it so ??? What does it mean
that energy is stored???(potential
energy)?????
ANSWER:
My, you
really are struggling. It is clear
that you are just beginning your
physics education, so I will keep my
answer addressed only at that level.
In fact, I will only discuss problem
involving a uniform gravitational
field. First, suppose we know
nothing about potential energy. So,
the example you give is taking a
ball of mass m and throwing
it up vertically with some velocity
v . Then it starts with
energy E 1 =½mv 2
and rises to some height h
where all its energy is gone, E 2 =0.
So energy was not conserved; why
not? Because some force must have
done work on the mass to take its
energy. Of course, that force is
gravity which is mg .
Because the force is constant and
pointing down and the displacement
is positive is positive, the work is
negative, W=-mgh . The work
done is equal to the change in
energy W=E 2 -E 1 =-mgh =0-½mv 2 .
You could use this to find out how
high the ball will go, h=v 2 /(2g );
you have probably done such a
problem before you knew anything
about potential energy.
I next want
to generalize this problem. The ball
is thrown vertically from a height
y 1 with a
velocity v 1 and
at a later time it is at different
height y 2 and
now has a velocity v 2 .
So now the work done is -mg (y 2 -y 1 )
and the change in energy is
½mv 2 2 -½mv 1 2 .
So, rearranging, I can now write (½mv 2 2 +mgy 2 )-(½mv 1 2 +mgy 1 )=0.
If there are no forces other than
gravity which are doing work on the
ball, the quantity ½mv 2 +mgy
never changes! So now I get the
brilliant idea (just one way of
looking at this problem) to call
K =½mv 2 the
energy due to motion (kinetic
energy) and V=mgh the
energy due to position (potential
energy). So you can call
gravitational potential energy a
clever trick which allows you to
never worry about calculating the
work done by gravity. Another great
reason to use potential energy is
that energy is a scalar quantity
whereas force is a vector quantity.
There are
some things you have to be careful
of. If you are using V=mgy
for gravitational potential energy,
you must choose a coordinate system
where +y is up; e.g .,
if the top of a cliff is at y =0
m, the bottom of the cliff cannot be
at y =100 m. You cannot use
potential energy for just any old
force, it has to be a conservative
force. A conservative force is one
which does zero total work over a
closed path (ending where you
started). E.g., gravity
does negative work on the ball and
positive work on the way down. If
you push a book across a table you
must do work against friction; but
now if you push it back it will be
the same amount of work so you
cannot have a potential for
friction. Your "famous rule" is not
very useful. I think you should
think in terms of the energy
equation, E final =E initial +W ext ,
the energy you end up with is the
energy you started with plus what
you added. W ext
is the work done by all external
forces, forces for which you have
not introduced a potential energy;
forces represented by potential
energy functions are not external,
you have internalized them.
QUESTION:
I saw an
older question on your site
regarding how fast Flash could run a
quarter mile. Using similar
assumptions, in Science Fantasy -
verse Warhammer 40000, there are
Space Marines who are biologically
enhanced super warriors with 19-22
implanted extra organs that make
them able to overwhelmingly
outperform a regular human. Space
Marines are roughly 7-8.5t tall
(depending on if it is earlier
variant with 19 organs or later one
with 22 organs then the height is on
the taller end of the spectrum) with
a mass of 750 pounds unarmoured.
Space Marines have been decribed
running 87 km/h taking six meter
strides. Seeing that much shorter
and less massive Flash could run
quarter mile in ten seconds giving a
velocity of 144 km/h, using the
formula, how fast would you put the
maximum velocity a Space Marine
could run given their mass of 750
pounds? Can you give one estimate
using the rubber boot sole, and one
for ceramite boot sole that their
armour is made of? And when a Space
Marine wears armour, his mass is
increased to 500-1000kg, so how does
wearing armour affect the maximum
velocity when affected by laws of
friction, gravity, etc...?
ANSWER:
Oh my,
you missed the whole point of that
caluclation. The mass does not
matter because the frictional force
he can exert without slipping is
proportional to his mass. And his
acceleration is inversely
proportional to his mass; just the
same reason why the acceleration of
a falling mass (in vacuum) is
independent of mass. And strength
doesn't matter either if he can
exert the maximum frictional force
without slipping, μ static mg.
QUESTION:
How an
ellipsoid object, say an American
football...ball is thrown through
the air. It shows projectile motion,
but the other interesting
observation is that the front of the
ball points in the direction of
travel. I have thought that air
resistance possibly applies unequal
torques on different sides of the
ball perhaps, but I read somewhere
that it has to do with gyroscopic
precession - that this axis is
different to the one for angular
frequency, and somehow that explains
it. I'm not sure though, any simpler
way to understand this?
ANSWER:
If we
were to pass the football with
spiral in a vacuum, the spin axis
would remain pointing in the same
direction because of conservation of
angular momentum; this is the case
for the lower trajectory shown in
the figure. In air, though, the
angular momentum mainly remains
pointing in the same direction as
the velocity of the ball. I always
am surprised to find an everyday
phenomenon the physics of which is
unexplained or explained only
recently. This is such a case and
was explained only recently (2020)
in a
paper in American Journal of
Physics . A more accessible
description of the phenomenon can be
found at
this link . Your hunch that the
air has something to do with it was
spot-on.
QUESTION:
so, tell
me if I'm wrong but if an object is
energy it doesn't have mass yet it
is still affected by gravity, but
you need mas to be affected by
gravity 1. why is energy still
affected by gravity 2. is there any
way whatsoever for something without
mass that isn't energy be affected
by gravity.
ANSWER:
No, you
do not "need mass to be affected by
gravity". The
only object we know which has no
mass is the photon (a quantum of
light). And because it moves, it
has kinetic energy which is
well-known; you shouldn't say that a
photon is energy though,
rather it has energy. When
a photon finds itself in a strong
gravitational field it does not go
in a straight line (as you see
things) which you might have
expected, but rather it follows the
curved lines of the space where the
gravity is; in other words, in a
curved space a curved line may be
the shortest distance between two
points. Your second question refers
to something which has
neither mass nor energy; that isn't
really something , is it?
QUESTION:
I hope
this question isnt stupid, also
English isnt my first language, but
here I go: People always say that
you can't travel faster than light
speed, but what is the point from
which you count the speed (0 m/s)?
Because the earth is already moving
through space, so would we need to
accelerate less when accelerating in
the same direction and more if we
accelerate in the direction it comes
from?
Follow up, may
be explained by the answer to the
first question: does the light
emitting from let's say a LED
travelling at 60mph reach a target
100 miles away faster than a
staionary LED (assuming we turn both
on the second they are next to each
other, so when the moving one passes
it)?
ANSWER:
One of
the triumphs of the theory of
relativity is that its success
validates the principle of
relativity: The laws of physics are
the same in all frames of reference.
From this principle we can deduce
that the speed of light in a vacuum
is independent of the motions of the
observer or the source. So that
answers your 'followup': a bystander
would see the two light flashes
arrive at the same time. Your main
question asks which frame of
reference may a moving object not
exceed the speed of light? Since all
observers see the same speed of
light, the answer is any frame.
QUESTION:
Dad I
have a (possibly) physics question:
how come tempered glass just
spontaneously combusts without any
apparent cause? I remember my old
roommate's shower fully falling
apart during the pandemic when no
one was even there
ANSWER:
Hi
Hannah! I don't think you mean
"spontaneously combust" because that
would mean burning/flaming. Glass
does spontaneously shatter or break
in unexpected circumstances,
however. I have answered variations
of this question several times (
e.g. ,
1 ,
2 ,
3 );
1 is probably the most complete.
QUESTION:
I have
been thinking about a question, like
how we can write the change in unit
vectors over a finite time interval,
now it
may
seem like a homework problem but
trust me it's not it's a genuine
question that I have been thinking
about. I know about the change in
unit vectors in an infinitesimally
small-time interval 'dt' and that
it's given by the magnitude of the
really small angle that the unit
vector has turned about, but what
about a change in the unit vector
over a finite time interval how can
we write that. I tried to find the
answer in many sources, but I was
unable to find any.
ANSWER:
It is not
really clear to me what you are
asking. If you are talking about
Cartesian coordinates, they never
change. But if you have a coordinate
system like spherical polar
coordinates, the directions of the
unit vectors are very dependent on
where a point happens to be. I will
use a two dimnensional polar
coordinate system where the vectors
have both radial and tangential
components to keep the answer from
being too complicated. The figure
shows a red dot moving along some
path (red dotted line) which shows
the path taken by the particle
between two times t 1
and t 2 . The unit
vectors are shown in green. If you
know those two locations you can see
that the unit vectors all rotate
through an angle θ 2 -θ 1
in the clockwise direction. The path
taken by the particle will be
described by some vector function
f which
has components fr
and fθ as shown
in the figure. So the average rate
of change of direction of unit
vectors is ω avg =Δθ /Δt =(θ 2 -θ 1 )/(t 2 -t 1 ).
QUESTION:
A ship
at the speed of light turns on
headlights, understand that a person
on that ship sees light go out at
the speed of light, relativity. What
does a person "see" from outside
that area of relativity? Can they
see that, is that currently
possible, what if, if not current?
Do they see a ship with no lights,
light but no ship, a spectrum of
both that equals the speed of light?
I am, and with more questions, being
as specific as possible: I find it
hard to articulate a concept from
the written word, please accept and
understand my ignorance/lack of
understanding!
ANSWER:
First of
all, no ship can travel "…at the
speed of light…" and I do not answer
questions which stipulate at or
faster than the speed of light. So I
will answer your question assunming
v =0.99c , 99% the
speed of light. As you say, an
observer on the ship sees the light
in front of him having a speed of
c regardless of how fast
the ship is moving. An observer
relative to whom the ship is moving
with speed 0.99c also would
measure the speed of the light to be
c . This is one of the
postulates of the theory of special
relativity: The speed of light in a
vacuum is independent of the motion
of the source or the observer.
However he would not
"see"
the same "color" of the light
because of the doppler shift.
Suppose that the light as seen by
the ship had a wavelength of 450
nm=4.5x10-7 m, blue; for
0.99c speed of the source the
doppler shifted wavelength would be
about 4.5 nm, low-energy x-rays.
Hence the stationary observer would
see nothing but if he could measure
the speed of the x-rays coming out
the front of the ship he would see
them as having a speed of c .
QUESTION:
Lenses/Mirrors
form real / virtual imgs. Let's
consider real images. My query is
how can mere interaction of light
waves create the exact same picture
of the source from which they
originated? Does this mean that
light carries some information in
itself and when it interacts /
superimposes, it creates the
beautiful picture called an "image".
To elaborate, light itself is not
coloured, but why can we see
coloured images (when the light is
reflected from the object) ?
ANSWER:
Imagine
an object to the left of a spherical
lens as seen in the figure. There is
an imaginary line drawn
perpendicular to the lens and
through its center call ed the optic
axis. There is some object
consisting of many colors. I have
chosen to look at just three points
in this object, one red, one blue,
and one green. Each rays from these
points illuminates exactly one point
where the image is formed; although
I have only drawn three rays for
each point, every ray passes through
the the same single point on the
image. Apart from size and whether
the image is inverted or not, the
image is an exact copy of the
object. Your statement that "…light
itself is not coloured…" is not
correct--the color of light is
determined by its wave length.
QUESTION:
Assuming
no engineering challenges like
parasitic losses in materials etc….
Is it theoretically possible to
take: Speaker A. Play a tone. 440hz.
Digitally. Using EXACTLY 100 watts
of power. Speaker B. Play a tone.
440hz. Digitally. Using EXACTLY 100
watts of power. Have speakers A and
B facing each other head on. EXACTLY
180 degrees. The 2 speakers are
playing the same note. Same signal,
timbre, frequency amplitude pitch
etc…. Would these two “sounds”
cancel out perfectly such that “in
between” there would be zero
“sound”. I understand that small
changes in angles and frequencies
will have enormous effects on there
and how the sound will dissipate if
this system is not perfectly
balanced from the get go. Very loud.
But if the experiment were set up
perfectly, is it theoretically
possible to zero out the wave? Full
100% destructive interference?
Chaos? Feigenbaum?
ANSWER:
No, the
result is a standing wave of the
same frequency. In the animation the
original waves from the left (blue)
and right (green) combine to make
the black waves which have the same
frequency and wavelength but zero
velocity. This is due to the
superposition principle which states
that if two or more waves are moving
in the same medium, the net
displacement is equal to the sum of
the individual displacements at each
time and location. Note that the
black curve is sometimes totally
zero, when the two traveling waves
are out of phase with other. If two
identical waves are traveling in the
same direction they could completely
cancel if they were 180° out of
phase. In the second (nonanimated)
gif, imagine the green and blue are
moving in the same direction. The
black would be the resultant wave.
QUESTION:
I am
trying to understand heat, that is,
mostly the idea of hot and hotter.
My understanding is that heat is
basically motion, and heating
something up (cooking, let's say) is
about transferring motion from one
place to another. So that the
changes that take place in cooking
are really caused by the molecules
of stuff rubbing against each other.
So hotter really means MORE motion,
because the actual temperature at
which things burn, like natural gas,
can't be increased just because you
burn more of it. Does that make some
sort of sense to you? Clearly my
mind wanders in the kitchen, and
this has been nagging at me for a
long time.
ANSWER:
I believe
that your question is answered by an
earlier answer . You refer to
motion; in my earlier answer the
kinetic energy referred to is K =½mv 2
where m is the mass of some
atom or molecule in your flame or
pot or food, and v is its
speed (motion).
QUESTION:
I have a
question about fluid
velocity/acceleration and its
effects on tubular friction. Is the
relationship linear? Meaning , if
the fluid velocity is being
increased, is there a moment or a
few moments where the friction
increases more than what it would’ve
been if the relationship was linear?
ANSWER:
From what
I have been able to learn while
researching your question is that
"friction" as in two solids sliding
on their surfaces is not applicable
to fluid inside a pipe. The fluid
exactly on the surface is not
sliding but rather adheres to the
surface and is at rest. The motion
of remainder of the fluid has some
velocity just outside the surface
increases to a maximum at the center
but certainly not linearly.
Everything about this velocity
profile is due to the viscosity of
the fluid, sort of the fluid version
of friction. More detail can be seen
in
this link and links which it
contains. The figure shows a figure
from that link and shows the shape
of the velocity profile, v (r ).
Eventually, at high enough speeds
the fluid becomes turbulent and "all
bets are off".
QUESTION:
How
should I get to calculating the
force that needs to be applied to a
piston to compress a container of
gas? Suppose the temperature is
constant, and by default, as the
volume decreases the pressure
increases. Let's suppose the volume
gets halved.
ANSWER:
The force
depends on the area A of
the piston. And, if the gas cannot
be well approximated as an ideal
gas, you would need detailed
properties about the gas. For an
ideal gas, PV /T
must remain constant and if T
is constant, PV is
constant. Now, it seems easy, like
if you halve the the volume you need
to double the pressure; that would
give you the answer for the force to
hold the piston there once you got
it there, F=P 2 A= 2P 1 A .
Be sure that you understand that
this is what you mean because if you
simply started at the beginning with
this force and continued pushing
with that force, when you got to the
half-volume position you would go
right by it and it would start
slowing down until finally it would
turn around and start coming back.
QUESTION:
For
reference I'm 31. Am I closer to the
age 60 than I am 20? I think I'm
closer to the age 60 because time is
moving forward and we cannot move
backwards to my age at 20. So
wouldn't I be closer to 60 because
time can only move in a linear
motion towards 60 and we are
constantly distancing ourselves from
the age of 20?
ANSWER:
You are
11 years older than 20 and 29 years
younger than 60. You are closer to
20 by almost a factor of 3. If you
had asked which you would be closer
to being, you would be closer to
being 60 than 20; but you didn't.
QUESTION:
Is a
mirror VERY different to how people
perceive me in reality? I am
bothered by the fact that I never
realised before but I guess there's
a reason… How impactful is the
reversal effect? I always thought
that's how I look to others.
ANSWER:
The image
you see is not how others see you,
but a "mirror image". If you look at
the image of yourself in the mirror,
the image of your right hand is the
left hand of the mirror you. If you
want to see an image of yourself
which is what others see, you need
to use a corner mirror. However,
since most of us are pretty much
left-right symmetrical, there is
seldom much difference.
QUESTION:
My eight
year old has a question. Get ready.
If two particles are in entangled,
and one is on the earth and the
other has passed the event horizon
of a black hole. Would the
entanglement be broken or even if
it's unmeasurable still be
entangled. Does the medium "the
ether" transcend the event horizon?
Silas Massicotte (8) and Malachi
Massicotte (6).
ANSWER:
Seriously? Your 8-year old
understands quantum mechanics and
cosmology?! That would be pretty
amazing. I usually don't do, as
stated on the site,
astronomy/astrophysics/cosmology,
but I did a little research and
think I can give you an answer. When
one of the two entangled particles
is totally destroyed, the other one
will not know at all because there
is no communication between the two.
Since the wave function of the
destroyed one simply disappeared,
the wave function of the other will
remain in the mixed state it was in
originally, but it will no longer be
entangled with anything. If a
measurement is made on the survivor,
there will be no change in whatever
remains of the other particle. There
is a pretty good explanation at this
link . There is no such thing as
the ether.
QUESTION:
how can
electromagnetic waves travel in
vacuum? how can something without
any physical body and dimensions
travel in nothing? it should need
something to mediate its propagation
like sound waves require air
molecules. if its pure energy then
what is pure energy?
ANSWER:
This is
exactly the way physicists were
thinking at the end of the 19th
century. Serious searches for the
medium required for light to be able
to propogate were being made. The
best known search was the
Michaelson-Morley experiment which
failed to find it. It was called the
luminferous æther. The punch line is
that it doesn't exist at all. Light
can travel through empty space. One
way to understand this is through
electro-magnetic theory, quite well
understood at the begining of the
20th century. James Clerk Maxwell
unified all that was known about
electromagnetism into four
equations, today known as
Maxwell's equations . One of
those equations says that
time-varying magnetic fields cause
electric fields; another says that
time-varying electric fields cause
magnetic fields. Using all four you
can show that one possible solution
is a wave equation for both electric
and magnetic fields. Since waves are
time-varying, these waves will "keep
each other going" which has nothing
to do with any medium. If you go to
the link above, you can follow other
links telling you more.