Free fall acceleration in SR

In summary: SR uses the inertial frames of classical mechanics; in my opinion it's obvious that SR doesn't predict that an accelerometer in free fall will indicate a large acceleration. That conflicts with the known laws of physics, even of classical mechanics.
  • #1
harrylin
3,875
93
This is a spin-off of a parallel discussion, starting from:
https://www.physicsforums.com/showthread.php?p=4281037#post4281037

The question is what SR predicts that an accelerometer in free-fall will read. This issue may be simply due to different people using a different meaning of "SR", but it could have a deeper cause.

A basic reference for this discussion:
Einstein 1905, http://www.fourmilab.ch/etexts/einstein/specrel/www/
and another one for context:
Langevin 1911, http://en.wikisource.org/wiki/The_Evolution_of_Space_and_Time

DaleSpam said:
As you make your [itex]\delta \tau[/itex] small the SR predicted accelerometer reading becomes large while the actual accelerometer reading remains 0. [..]
DaleSpam said:
[..] SR predicts a very large accelerometer reading during the turnaround, and real free falling accelerometers read 0.
SR uses the inertial frames of classical mechanics; in my opinion it's obvious that SR doesn't predict that an accelerometer in free fall will indicate a large acceleration. That conflicts with the known laws of physics, even of classical mechanics.

Arguments in favor of both opinions may help to clarify this issue.
 
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  • #2
SR predicts that an ideal accelerometer reads:[tex]a^{\mu}=\frac{d^2 x^{\mu}}{d\tau^2}[/tex]Where x is the worldline of the accelerometer in a SR inertial frame and τ is the proper time along that worldline.

If you claim that a frame can be treated as a SR inertial frame, then the above formula is what SR predicts for the proper acceleration of objects.

harrylin said:
The question is what SR predicts that an accelerometer in free-fall will read.
That question cannot even be addressed by SR since SR does not handle gravitation. You cannot generally establish a self-consistent SR inertial frame in the presence of gravity. This question is outside the domain of applicability of SR.

The real question is when is it appropriate to use SR as an approximation in a scenario where there is gravity. The answer to that question is that it is appropriate to do so when the resulting errors for the measured quantities in the scenario are small. That is not the case in a gravitational turn-around twin scenario.
 
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  • #3
DaleSpam said:
SR predicts that an ideal accelerometer reads:[tex]a^{\mu}=\frac{d^2 x^{\mu}}{d\tau^2}[/tex]Where x is the worldline of the accelerometer in a SR inertial frame and τ is the proper time along that worldline.

If you claim that a frame can be treated as a SR inertial frame, then the above formula is what SR predicts for the proper acceleration of objects. [..]
Your definition does not appear in the provided references which don't even use that term; I can find no reason for expecting such a flagrant error in SR. The first reference defines SR wrt the inertial frames of classical mechanics; wrt such frames the laws of Newton hold in good approximation. An ideal accelerometer that in free fall reads zero would be a colossal erroneous modification of Newton's mechanics. Please provide a reliable reference to back up that claim.
[...] You cannot generally establish a self-consistent SR inertial frame in the presence of gravity. [..]
SR was always assumed to be applicable on Earth (of course, in good approximation!); for example CERN uses it in the presence of gravity.
The real question is when is it appropriate to use SR as an approximation in a scenario where there is gravity. The answer to that question is that it is appropriate to do so when the resulting errors for the measured quantities in the scenario are small. That is not the case in a gravitational turn-around twin scenario.
That's certainly not the topic of this thread, and the preliminary discussion was from about here: https://www.physicsforums.com/showthread.php?p=4281150. I hold that by design the resulting error for that case must be small whatever the details of the turn-around, as it was meant to be of sufficiently short duration to be neglected. It's certainly worthy of its own thread, with a detailed calculation.
 
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  • #4
DaleSpam said:
SR predicts that an ideal accelerometer reads:[tex]a^{\mu}=\frac{d^2 x^{\mu}}{d\tau^2}[/tex]Where x is the worldline of the accelerometer in a SR inertial frame and τ is the proper time along that worldline.

You can say that that's true by definition of "ideal accelerometer", but you can't prove that there is any actual device that is an ideal accelerometer.

The canonical example of an accelerometer that I always use is a cubical box, with a ball suspended in the center by 6 identical springs connected to the center of each wall of the box. You measure acceleration by the deflection of the ball from the center.

But if there were a force that pulled springs, ball and box in proportion to their masses, then acceleration due to this force would not be measurable.

Another alternative for an accelerometer is to use light beams: if the light beam travels straight, then the device producing the beam is not accelerating. If the light beam curves in one direction or another, then that indicates acceleration. Maybe this can be used to measure acceleration? It all depends on whether light itself is affected by forces.
 
  • #5
harrylin said:
An ideal accelerometer that in free fall reads zero would be a colossal erroneous modification of Newton's mechanics. Please provide a reliable reference to back up that claim.
Did you mean to write this ? You must mean something completely different from what I understand to be 'free fall'.
 
  • #6
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  • #7
stevendaryl said:
The canonical example of an accelerometer that I always use is a cubical box, with a ball suspended in the center by 6 identical springs connected to the center of each wall of the box. You measure acceleration by the deflection of the ball from the center.

But if there were a force that pulled springs, ball and box in proportion to their masses, then acceleration due to this force would not be measurable.
That is correct. The only such forces within the domain of applicability of SR are fictitious forces, and fictitious forces are not measured by accelerometers. The only other such force in any mainstream theory is Newtonian gravity, which is incompatible with SR and therefore outside its domain of applicability.

stevendaryl said:
Another alternative for an accelerometer is to use light beams: if the light beam travels straight, then the device producing the beam is not accelerating. If the light beam curves in one direction or another, then that indicates acceleration. Maybe this can be used to measure acceleration? It all depends on whether light itself is affected by forces.
I believe that one consequence of the first postulate is that your mechanical and your optical accelerometers will read the same.
 
  • #9
Mentz114 said:
Did you mean to write this ? You must mean something completely different from what I understand to be 'free fall'.
I would like to know what he/she meant by that too because it certainly isn't my understanding of free fall.
 
  • #10
Mentz114 said:
Did you mean to write this ? You must mean something completely different from what I understand to be 'free fall'.

I wasn't sure about that, either, but he might mean that according to Newtonian physics, an object in freefall is accelerating under the force of gravity. So an "accelerometer" that measures zero in freefall isn't correctly measuring the Newtonian notion of acceleration. But then, that just means that there is no (localized) device that can measure acceleration in the Newtonian sense.
 
  • #11
WannabeNewton said:
I would like to know what he/she meant by that too because it certainly isn't my understanding of free fall.

stevendaryl said:
I wasn't sure about that, either, but he might mean that according to Newtonian physics, an object in freefall is accelerating under the force of gravity. So an "accelerometer" that measures zero in freefall isn't correctly measuring the Newtonian notion of acceleration. But then, that just means that there is no (localized) device that can measure acceleration in the Newtonian sense.

Yes, I guess that's what he means. In the other thread GregAshmore mentions 'unbalanced forces'. I suppose an accelerometer can be said to measure resistance ( reaction ) to an applied force ( speaking in Newtonian terms ).

It shows how tricky gravity is an why it makes sense to geometrise it.
 
  • #12
harrylin said:
SR doesn't predict that an accelerometer in free fall in flat spacetime will indicate a large acceleration.

You should have included the bolded phrase; as DaleSpam pointed out, it's crucial. SR can't deal with curved spacetime; the spacetime in the "gravitational turnaround" scenario, where the traveling twin is in free fall the whole time, is curved. It has to be, otherwise the traveling twin couldn't be in free fall the whole time.
 
  • #13
harrylin said:
SR was always assumed to be applicable on Earth (of course, in good approximation!); for example CERN uses it in the presence of gravity when the approximation is good enough.

You left out a phrase here too, and again it's crucial. The CERN people don't analyze experiments including the effects of gravity; they analyze experiments in a local inertial frame in which the effects of gravity are negligible. That's why they can use SR for the analysis: because SR is still valid within a local inertial frame.
 
  • #14
Mentz114 said:
Did you mean to write this ? You must mean something completely different from what I understand to be 'free fall'.
Obviously I did not, thanks for pointing that out! Indeed, I meant the inverse, as I stated earlier and even in my first post here. An ideal [mechanical] accelerometer that in free fall doesn't read zero would be a colossal erroneous modification of Newton's mechanics.
 
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  • #15
DaleSpam said:
See these references:
http://physicspages.com/2011/05/25/acceleration-in-special-relativity/
http://www.mth.uct.ac.za/omei/gr/chap2/node2.html [Broken] and http://www.mth.uct.ac.za/omei/gr/chap2/node4.html [Broken]
http://en.wikipedia.org/wiki/Four-velocity#Definition_of_the_four-velocity and http://en.wikipedia.org/wiki/Four-acceleration

The formula is correct. If you disagree, then please provide the formula you believe is correct.
I checked your first two references, which according to my browser do not even contain the word "accelerometer". I didn't look further.

ADDENDUM: I overlooked that you asked me to state the obvious. You suggest(ed?) that SR proposed laws that were known to be erroneous. All parts of an accelerometer fall at the same rate in a homogeneous field; to suggest that according to SR this known fact would not be true not only makes no sense to me, it also doesn't follow from either the postulates or the Lorentz transformations.

BTW, I suddenly notice in post #2 a change of opinion about the SR predicted accelerometer reading; that's good, it means that such discussions have merit. :smile: It's very well possible that I'll similarly change my opinion, but I need to see some substantial argument.
 
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  • #16
DaleSpam said:
[..] I believe that one consequence of the first postulate is that your mechanical and your optical accelerometers will read the same.
That could be a lead; please elaborate.
 
  • #17
PeterDonis said:
You should have included the bolded phrase; as DaleSpam pointed out, it's crucial. SR can't deal with curved spacetime; the spacetime in the "gravitational turnaround" scenario, where the traveling twin is in free fall the whole time, is curved. It has to be, otherwise the traveling twin couldn't be in free fall the whole time.
With "fall" I mean the standard meaning of "falling" in SR and English, of a freely moving object in a gravitational field. That is in contrast to "inertial".
 
  • #18
PeterDonis said:
You left out a phrase here too, and again it's crucial. The CERN people don't analyze experiments including the effects of gravity; they analyze experiments in a local inertial frame in which the effects of gravity are negligible. That's why they can use SR for the analysis: because SR is still valid within a local inertial frame.
The surface of the Earth is not a local inertial frame, but as discussed earlier we fully agree on the fact that we work with approximations. You appear to hold that SR doesn't make any prediction in a gravitational field. However, CERN certainly is in a gravitational field.
 
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  • #19
harrylin said:
You appear to hold that SR doesn't make any prediction in a gravitational field.

No, I said that SR can't explain how the traveling twin in the Langevin version of the twin paradox doesn't feel any force during the turnaround. You can still derive the difference in proper time between the stay-at-home twin and the traveling twin using SR, by making the inertial legs very long compared to the turnaround; but that doesn't explain how the turnaround can be made in free fall. And you can't finesse this by saying "well, it's all in a local inertial frame", because the free-fall turnaround cannot be made within a single local inertial frame. This is a crucial difference between that case and the CERN case; CERN experiments can be analyzed within a single local inertial frame because they happen so fast and over such a short span of distance compared to the size of the Earth.
 
  • #20
harrylin said:
I checked your first two references, which according to my browser do not even contain the word "accelerometer". I didn't look further.
The definition I gave and the pages I linked to give the formula for the four velocity and explain it's relationship to proper acceleration and the coordinate acceleration in the momentarily comoving inertial frame. I am sure that you are aware that proper acceleration is the acceleration measured by an accelerometer.

harrylin said:
ADDENDUM: I overlooked that you asked me to state the obvious.
What I asked you to state is the formula that you believe SR uses to predict the reading on an accelerometer, which, with characteristic evasiveness, you have failed to do.

This has become a pattern with you. I refer to some unambiguous mathematical expression, you claim it is wrong, I ask you to provide what you believe to be the correct mathematical expression, and you fail to do so, over, and over, and over, ...
 
  • #21
PeterDonis said:
No, I said that SR can't explain how the traveling twin in the Langevin version of the twin paradox doesn't feel any force during the turnaround.
SR merely makes predictions. This thread examines the repeated claim elsewhere that SR predicts a large accelerometer reading in free fall, which is contrary to the known facts at the time of SR's inception.
You can still derive the difference in proper time between the stay-at-home twin and the traveling twin using SR, by making the inertial legs very long compared to the turnaround; but that doesn't explain how the turnaround can be made in free fall. And you can't finesse this by saying "well, it's all in a local inertial frame", because the free-fall turnaround cannot be made within a single local inertial frame. This is a crucial difference between that case and the CERN case; CERN experiments can be analyzed within a single local inertial frame because they happen so fast and over such a short span of distance compared to the size of the Earth.
Similarly, Langevin's example could be analyzed within one, resp. two universal inertial frames (the ones of SR) because the turn-around was supposed to happen so fast and over such a short time span compared to the duration of the trip that this should be irrelevant for the calculation; however both for CERN as well as Langevin we can only be certain if we do a GR estimation, and it is off-topic here. If you would like to do so, please start it as a new topic; that will be interesting indeed!
 
  • #22
DaleSpam said:
The definition I gave and the pages I linked to give the formula for the four velocity and explain it's relationship to proper acceleration and the coordinate acceleration in the momentarily comoving inertial frame. I am sure that you are aware that proper acceleration is the acceleration measured by an accelerometer.
In the other thread we discussed different definitions of "proper acceleration", and which are irrelevant for a prediction about an accelerometer reading in free fall. Here in the lab we have set up several student experiments with accelerometers, which is why I'm particularly attentive to such things.
What I asked you to state is the formula that you believe SR uses to predict the reading on an accelerometer, which, with characteristic evasiveness, you have failed to do. [..]
The reading of a standard and good accelerometer (mechanical) in free fall can only be zero; I know no postulate of SR that changes that fact. So if you really want this stated as an equation: the following should be approximately true in general and exactly true in free fall for a mechanical accelerometer according SR:
Fbending = m(g-a) = 0 -> adisplayed = "0".

And once more: I did not consider what prediction SR would make for an optical accelerometer; that's an interesting variant.
Addendum: After short consideration I expect SR to predict that an optical accelerometer will indicate acceleration in a gravitational field.
 
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  • #23
An interesting historical note to this thread, which I hope does not distract the discussion, is that in 1911, the same year as Langevin's paper, Einstein had already predicted that any theory of gravity consistent with relativity must include gravitational time dilation. If Langevin had any inkling of this, he certainly made no mention of it in his 1911 paper.
 
  • #24
PAllen said:
An interesting historical note to this thread, which I hope does not distract the discussion, is that in 1911, the same year as Langevin's paper, Einstein had already predicted that any theory of gravity consistent with relativity must include gravitational time dilation. If Langevin had any inkling of this, he certainly made no mention of it in his 1911 paper.
I also thought about that fact; however in my thinking (post #21) he had sufficient reason not to mention that detail. More about this would indeed distract from the discussion here.
 
  • #25
harrylin said:
the following should be approximately true in general and exactly true in free fall for a mechanical accelerometer according SR:
Fbending = m(g-a) = 0 -> adisplayed = "0".
Please define your terms. Assuming that g is the acceleration due to gravity from some gravitating masses, then to me this equation seems obviously incompatible with SR. Specifically, there is no way to calculate g in SR.

Please provide a reference for this formula. Specifically, a reference or combination of references which shows that this formula is the formula for SR. Or, at a minimum, a reference for g in SR.

harrylin said:
Addendum: After short consideration I expect SR to predict that an optical accelerometer will indicate acceleration in a gravitational field.
If this were true, then mechanical systems and optical systems would have different sets of inertial frames. Which would violate the first postulate.
 
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  • #26
DaleSpam said:
If this were true, then mechanical systems and optical systems would have different sets of inertial frames. Which would violate the first postulate.

I think this is a matter of semantics. Einstein defined an "inertial frame" (or rather, an inertial coordinate system) to be one where Newton's laws held (approximately, anyway). You get a different answer as to "what frames are inertial" depending on whether you consider gravity to be a "force" or not.

Newton's laws of motion work either way: You can consider a falling particle to be traveling inertially, or you can consider it to be accelerating under the influence of the force of gravity.

So the application of the principle of relativity (the equivalence of inertial frames) to gravity is ambiguous.
 
  • #27
stevendaryl said:
I think this is a matter of semantics. Einstein defined an "inertial frame" (or rather, an inertial coordinate system) to be one where Newton's laws held (approximately, anyway). You get a different answer as to "what frames are inertial" depending on whether you consider gravity to be a "force" or not.
I agree that it is a matter of semantics, specifically, the semantics of how an inertial frame is defined. But since inertial frames are part of the first postulate this semantic issue can still violate the first postulate, i.e. such a definition of inertial frames (semantics) is incompatible with the first postulate.
 
  • #28
DaleSpam said:
I agree that it is a matter of semantics, specifically, the semantics of how an inertial frame is defined. But since inertial frames are part of the first postulate this semantic issue can still violate the first postulate, i.e. such a definition of inertial frames (semantics) is incompatible with the first postulate.

If optical phenomena in freefall worked differently than mechanical phenomena in freefall, then that would mean that freefall could not be considered an inertial frame. That wouldn't contradict the relativity principle by itself.
 
  • #29
stevendaryl said:
If optical phenomena in freefall worked differently than mechanical phenomena in freefall, then that would mean that freefall could not be considered an inertial frame. That wouldn't contradict the relativity principle by itself.
I see what you are saying. I have a feeling that it still contradicts the first postulate, but it isn't as straight forward as I thought at first. I will try to work it out.
 
  • #30
Interesting topic...
Apologies to everyone if I happen to break the thread :p
But I feel the question is nonsensical without very precise definitions... like perhaps, what is an accelerometer, or actually more importantly, what is free fall? That last bit might have us ask what is gravity, or maybe more generally what is a force field (no, not the star trek kind).
You might be thinking the definition is trivial, just map a force to every point in space... but oh wait, it is not actually a fixed force, rather a function of mass so it produces a fixed acceleration... but oh wait, its not even fixed acceleration, wouldn't it also have to be a function of velocity because of all the relativity stuff...
And what about the specific properties of it, and how they are affected by SR coordinate transforms? Is a uniform force field also uniform in other frames? Is a constant force field also constant in other frames? No...
You might be looking at a train (or accelerometer) at rest, and watching it gradually speed up, completely uniformly and with no deformation, and thinking... wow, this must be gravity moving it... yet someone in some other reference frame would be watching that initially uniformly moving train get deformed and say, hey, this can't be gravity, unless we are so close to a black hole or something.
This whole thing is confusing to me.
 
  • #31
harrylin said:
SR merely makes predictions.

Fine, s/explain/predict/ in what I wrote; it's still true.

harrylin said:
This thread examines the repeated claim elsewhere that SR predicts a large accelerometer reading in free fall

I haven't made any such claim, and I don't think anyone else has either. I agree, and I suspect all the others here do too, that SR predicts zero accelerometer reading in free fall. What SR doesn't predict is that a worldline curving around a star the way the turnaround worldline of the traveling twin has to will be in free fall. You need GR to predict that.

harrylin said:
Similarly, Langevin's example could be analyzed within one, resp. two universal inertial frames (the ones of SR) because the turn-around was supposed to happen so fast and over such a short time span compared to the duration of the trip that this should be irrelevant for the calculation

For the calculation of total proper time, yes. But not for the calculation of what an accelerometer will read during the turnaround. There's no way to do such a calculation in a single local inertial frame.

harrylin said:
however both for CERN as well as Langevin we can only be certain if we do a GR estimation

But what you will be "certain" of is two very different things:

In the CERN case, you'll just be confirming that any single CERN experiment can be analyzed in a single local inertial frame: the corrections from spacetime curvature are too small to matter. So you'll just be confirming that the SR calculation you do in a single local inertial frame is valid to within a good enough approximation.

In the Langevin case, you'll be actually doing a calculation (of the accelerometer reading during the turnaround) that can't be done at all with SR, because it can't be done within a single local inertial frame.
 
  • #32
harrylin said:
With "fall" I mean the standard meaning of "falling" in SR and English, of a freely moving object in a gravitational field. That is in contrast to "inertial".

I don't understand the contrast you're trying to make here. Doesn't "freely moving" mean the same thing as "inertial"?
 
  • #33
stevendaryl said:
I think this is a matter of semantics. Einstein defined an "inertial frame" (or rather, an inertial coordinate system) to be one where Newton's laws held (approximately, anyway). You get a different answer as to "what frames are inertial" depending on whether you consider gravity to be a "force" or not.
I thought more about this until I got tired. Then I realized that it doesn't matter. There is no theory of gravity which is compatible with SR, so the question never comes up if it is considered a force or not. You have to go to GR for a relativistic theory of gravity. All you can do in SR is to neglect gravity. The validity of neglecting gravity depends on how large the resulting errors are.
 
  • #34
If the question was about the Newtonian case, I would answer accelerometers will read zero. In the simple Newtonian case, any global uniform force is undetectable in a closed experiment. Accelerometers will not detect uniform forces, which gravity can be considered to be... approximately.
It is not completely uniform, as it is directed towards a point and dependent on the distance, and this slight non-uniformity might be possible to detect, i.e. we might be able to build some kind of "accelerometer" (gravitymeter?) based on that... but I don't think this is relevant to the question. I assume the non-uniformity should be considered small enough to be disregarded.

Somehow intuitively, I'd expect the same answer for SR, by extension. The problem is the definition of a global uniform force in that context, though.
 
  • #35
DaleSpam said:
[..] Specifically, there is no way to calculate g in SR.
Please provide a reference for this formula. [.] Or, at a minimum, a reference for g in SR.
Neither of us knows such a reference, but we made contrary claims about what we think SR predicts for that case. The purpose of this thread is to find out what SR predicts, based on the foundations. SR is based on Maxwell's electrodynamics as well as Newton's mechanics, but makes well known corrections to Newton''s mechanics. I think that it's easy to show that my interpretation is correct, by making those corrections to the standard classical equations.
[..] then mechanical systems and optical systems would have different sets of inertial frames. Which would violate the first postulate.
I think that you misapply a GR definition to SR. The postulates are defined wrt the reference systems of Newton's mechanics and gravity is a force in SR. Please explain how you think that gravitational attraction of matter but not of EM waves can violate the first postulate.
 
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<h2>1. What is free fall acceleration in special relativity (SR)?</h2><p>Free fall acceleration in special relativity is the acceleration experienced by an object in a gravitational field in the absence of any external forces. It is a fundamental concept in Einstein's theory of special relativity, which describes the behavior of objects moving at high speeds or in the presence of strong gravitational fields.</p><h2>2. How is free fall acceleration different in SR compared to classical physics?</h2><p>In classical physics, free fall acceleration is considered to be a constant value of 9.8 m/s², regardless of the mass of the object. However, in special relativity, the acceleration experienced by an object in free fall is dependent on the object's mass and the strength of the gravitational field it is in.</p><h2>3. How does time dilation affect free fall acceleration in SR?</h2><p>In special relativity, time dilation occurs when an object is moving at high speeds or in a strong gravitational field. This means that time appears to pass slower for an object experiencing free fall acceleration in SR compared to an object at rest. This effect is known as gravitational time dilation and is a consequence of Einstein's theory of general relativity.</p><h2>4. Can free fall acceleration in SR be measured experimentally?</h2><p>Yes, free fall acceleration in special relativity can be measured experimentally using devices such as accelerometers or by observing the motion of objects in a gravitational field. These measurements have been confirmed to be consistent with the predictions of Einstein's theory of special relativity.</p><h2>5. How does the concept of equivalence principle relate to free fall acceleration in SR?</h2><p>The equivalence principle is a fundamental concept in Einstein's theory of general relativity, which states that the effects of gravity are equivalent to the effects of acceleration. This means that an object experiencing free fall acceleration in a gravitational field in special relativity is equivalent to an object accelerating in the absence of a gravitational field. This principle helps to explain the behavior of objects in free fall in both special and general relativity.</p>

1. What is free fall acceleration in special relativity (SR)?

Free fall acceleration in special relativity is the acceleration experienced by an object in a gravitational field in the absence of any external forces. It is a fundamental concept in Einstein's theory of special relativity, which describes the behavior of objects moving at high speeds or in the presence of strong gravitational fields.

2. How is free fall acceleration different in SR compared to classical physics?

In classical physics, free fall acceleration is considered to be a constant value of 9.8 m/s², regardless of the mass of the object. However, in special relativity, the acceleration experienced by an object in free fall is dependent on the object's mass and the strength of the gravitational field it is in.

3. How does time dilation affect free fall acceleration in SR?

In special relativity, time dilation occurs when an object is moving at high speeds or in a strong gravitational field. This means that time appears to pass slower for an object experiencing free fall acceleration in SR compared to an object at rest. This effect is known as gravitational time dilation and is a consequence of Einstein's theory of general relativity.

4. Can free fall acceleration in SR be measured experimentally?

Yes, free fall acceleration in special relativity can be measured experimentally using devices such as accelerometers or by observing the motion of objects in a gravitational field. These measurements have been confirmed to be consistent with the predictions of Einstein's theory of special relativity.

5. How does the concept of equivalence principle relate to free fall acceleration in SR?

The equivalence principle is a fundamental concept in Einstein's theory of general relativity, which states that the effects of gravity are equivalent to the effects of acceleration. This means that an object experiencing free fall acceleration in a gravitational field in special relativity is equivalent to an object accelerating in the absence of a gravitational field. This principle helps to explain the behavior of objects in free fall in both special and general relativity.

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