Proper time of accelerated clocks

In summary, the proper time of a clock under acceleration has been a topic of discussion in other threads. For this analysis, two clocks are initially at rest and are simultaneously born-rigid accelerated along the x-axis, maintaining constant proper separation. The experiment takes place in flat space and when the clocks reach a velocity v relative to the initial frame, they maintain constant velocity. The proper time that elapses for each clock is determined by the acceleration and coordinate time, as shown in the equations provided. It is noted that maintaining constant proper separation does not keep the clocks naturally synchronized and there is no known acceleration scheme that can do so.
  • #1
yuiop
3,962
20
In other threads the topic of how the proper time of a clock under acceleration has come up a number of times so I have decided to analyse this subject in a little more detail.

For this analysis we have these conditions:

a)Two clocks are initially at rest separated by a distance [itex]L_o[/itex] along the x axis.
b) Both clocks are simultaneously born-rigid accelerated along the x-axis (maintaining constant proper separation).
c) The experiment happens in flat space.
d) When the rear clock reaches velocity v relative to the initial frame it stops accelerating and maintains constant velocity v.
e) When the front clock reaches velocity v relative to the initial frame it stops accelerating and maintains constant velocity.
f) In the final state both clocks have constant and equal velocity and are separated by the proper distance [itex]L_o[/itex]

Referring to the attached diagram:

[itex] a_F [/itex] is the acceleration of the front clock proportional to [itex]c^2/x_F[/itex]

[itex] a_R [/itex] is the acceleration of the rear clock proportional to [itex]c^2/x_R[/itex]

[itex] t_F [/itex] is the coordinate time that the front clock clock takes to get to velocity v.

[itex] t_R [/itex] is the coordinate time that the rear clock clock takes to get to velocity v.

The dashed green line from the origin going through [itex]T_{R1}[/itex] and [itex]T_F[/itex] is a line of simultaneity in the accelerated clock frame.

The red lines are constant velocity phase after the acceleration phase.


When the front clock stops accelerating the proper time that has elapsed ([itex]t_f[/itex]) is given by the formula:

(Eq 1) [tex]T_F = { c \over a_F} \sinh^{-1} \left({a_F t_F \over c} \right)[/tex]

When the rear clock stops accelerating the proper time that has elapsed ([itex]t_R[/itex]) is given by the formula:

(Eq 2) [tex]T_{R1} = { c \over a_R} \sinh^{-1} \left({a_R t_R \over c} \right)[/tex]

The rear clock accelerates faster and gets to velocity v quicker than the front clock. The proper time that elapses from the coordinate time the rear clock stops accelerating to coordinate time that the front clock stops accelerating is simply the coordinate time difference adjusted by the Lorentz factor:

(Eq 3) [tex]T_{R2} - T_{R1} = (t_f - t_r)\sqrt{1-v^2/c^2}[/tex]

The difference in proper time between the front clock and the rear clock after accelerating is given by

(Eq 4) = (Eq1) - (Eq 2) - (Eq 3)

The following equations are generally known:

(Eq 5) [tex] a=\sqrt{\left({c^4 \over x^2-c^2 t^2} \right)}[/tex]

(Eq 6) [tex] v={a t \over \sqrt{\left(1+(a t /c)^2\right)}}[/tex]

and the acceleration of the front clock in terms of acceleration of the rear clock can easily be derived as :

(Eq 7) [tex] a_F = {a_R c^2 \over (L_o a_R +c^2) [/tex]

By substituting (Eq 5), (Eq 6) and (Eq 7) into (Eq 4) and solving the time difference between the front and rear clocks as seen in the initial frame is given by:

(Eq 8) [tex] T_F - T_{R2} = {-L_o v \over c^2} + {L_o \over c} \sinh^{-1} \left({ v \over c \sqrt{1-v^2/c^2}} \right)[/tex]

When the clocks are synchronised again it is well known that:

(Eq 9) [tex] T_F - T_{R2} = {-L_o v \over c^2} [/tex]


It is interesting to note that the difference in the proper times of the clocks after born-rigid acceleration and before synchronisation (Eq 8) is completely determined by the final velocity and the proper spatial separation and is independent of the rate of acceleration or time taken to transfer from one frame to another.

It is obvious from (Eq 8) that if constant proper separation is maintained the clocks will not remain naturally synchronised.

It is further conjectured that there is no acceleration scheme that can keep two spatially separated clocks synchronised when transferring the clocks from one inertial reference frame to another.*

I have left quite a few gaps in the derivation to try and keep it brief, but I will fill the gaps in, if anyone is really interested.

[EDIT] *I found a counter proof to this conjecture in post #9. (This does not change the validity of (Eq 8) in the above context of born-rigid transportation.
 

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  • #2
Interesting. The result is counter-intuitive because of the asymmetry.
What about a simular situation where the clocks are alined in a perpendicular direction instead of in the direction of acel?
Any asymmetry in the final time frame there?

Has this equation been experimentally verified? Reference?
 
  • #3
kev said:
In other threads the topic of how the proper time of a clock under acceleration has come up a number of times so I have decided to analyse this subject in a little more detail.

For this analysis we have these conditions:

a)Two clocks are initially at rest separated by a distance [itex]L_o[/itex] along the x axis.
b) Both clocks are simultaneously born-rigid accelerated along the x-axis (maintaining constant proper separation).
c) The experiment happens in flat space.
d) When the rear clock reaches velocity v relative to the initial frame it stops accelerating and maintains constant velocity v.
e) When the front clock reaches velocity v relative to the initial frame it stops accelerating and maintains constant velocity.
f) In the final state both clocks have constant and equal velocity and are separated by the proper distance [itex]L_o[/itex]

Referring to the attached diagram:

[itex] a_F [/itex] is the acceleration of the front clock proportional to [itex]c^2/x_F[/itex]

[itex] a_R [/itex] is the acceleration of the rear clock proportional to [itex]c^2/x_R[/itex]

[itex] t_F [/itex] is the coordinate time that the front clock clock takes to get to velocity v.

[itex] t_R [/itex] is the coordinate time that the rear clock clock takes to get to velocity v.

The dashed green line from the origin going through [itex]T_{R1}[/itex] and [itex]T_F[/itex] is a line of simultaneity in the accelerated clock frame.

The red lines are constant velocity phase after the acceleration phase.


When the front clock stops accelerating the proper time that has elapsed ([itex]t_f[/itex]) is given by the formula:

(Eq 1) [tex]T_F = { c \over a_F} \sinh^{-1} \left({a_F t_F \over c} \right)[/tex]

When the rear clock stops accelerating the proper time that has elapsed ([itex]t_R[/itex]) is given by the formula:

(Eq 2) [tex]T_{R1} = { c \over a_R} \sinh^{-1} \left({a_R t_R \over c} \right)[/tex]

The rear clock accelerates faster and gets to velocity v quicker than the front clock. The proper time that elapses from the coordinate time the rear clock stops accelerating to coordinate time that the front clock stops accelerating is simply the coordinate time difference adjusted by the Lorentz factor:

(Eq 3) [tex]T_{R2} - T_{R1} = (t_f - t_r)\sqrt{1-v^2/c^2}[/tex]

Very interesting, nice work.
How do you reconcile (eq3) with the fact that, as seen from your Minkowski diagram:

[tex]T_{R2} = { c \over a_R} \sinh^{-1} \left({a_R t_r \over c} \right)[/tex] ?
 
  • #4
meemoe_uk said:
Interesting. The result is counter-intuitive because of the asymmetry.
What about a simular situation where the clocks are alined in a perpendicular direction instead of in the direction of acel?
Any asymmetry in the final time frame there?

No, clocks exactly perpendicular to a clock on the x-axis and syncronised with that clock, will remain syncronised with that clock when the acceleration occurs purely along the x axis.


meemoe_uk said:
Has this equation been experimentally verified? Reference?

I used equations from the following sources:

http://math.ucr.edu/home/baez/physics/Relativity/SR/rocket.html [Broken]

http://en.wikipedia.org/wiki/Hyperbolic_motion_(relativity [Broken])

http://www.mathpages.com/home/kmath422/kmath422.htm

The final result obtained in (Eq 8) is my own work. I am hoping the experts on this forum can confirm that the maths and logic is correct.

P.S. The diagram was created using a free geometry software program (called CaR) that can plot functions and evaluate expressions. That software at least confirms that (Eq 8) = (Eq 1) - (Eq 2) - (Eq 3)

For software that does not handle hyperbolic functions (Eq 8) can be expressed in the alternative form:

[tex] T_F - T_{R2} = {-L_o v \over c^2} + L_o c \log \left( \left({ v \over c \sqrt{1-v^2/c^2}} \right) + \sqrt{\left({ v \over c \sqrt{1-v^2/c^2}} \right)^2 +1 \right) [/tex]

using the general relation

[tex] \sinh^{-1}(x) = \log\left(x+ \sqrt{x^2+1}\right) [/tex]

where log is natural logarithm.
 
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  • #5
1effect said:
Very interesting, nice work.
How do you reconcile (eq3) with the fact that, as seen from your Minkowski diagram:

[tex]T_{R2} = { c \over a_R} \sinh^{-1} \left({a_R t_r \over c} \right)[/tex] ?


The rear clock maintains constant velocity from [itex]T_{R1}[/itex] to [itex]T_{R2}[/itex] (the straight diagonal red line) so the hyperbolic motion equations are not required for that segment and the straight forward Lorentz transformation of the time inteval is sufficient to obtain (Eq 3).

The total proper time experienced by the front clock is given by (Eq 1)

The total proper time experienced by the rear clock is (Eq 2) + (Eq 3)

The rear clock has a combination of hyperbolic motion and constant velocity.
 
  • #6
kev said:
The rear clock maintains constant velocity from [itex]T_{R1}[/itex] to [itex]T_{R2}[/itex] (the straight diagonal red line) so the hyperbolic motion equations are not required for that segment and the straight forward Lorentz transformation of the time inteval is sufficient to obtain (Eq 3).

The total proper time experienced by the front clock is given by (Eq 1)

The total proper time experienced by the rear clock is (Eq 2) + (Eq 3)

The rear clock has a combination of hyperbolic motion and constant velocity.

OK, I understand, you have some typos in the text and in the diagram that threw me off.
So, you are trying to calculate [tex]Ttotal_F-Ttotal_R[/tex], right?
But, in eq(8) you are calculating:

[tex]Ttotal_F-T_R_2[/tex], unless it is another typo?
 
  • #7
1effect said:
OK, I understand, you have some typos in the text and in the diagram that threw me off.
So, you are trying to calculate [tex]Ttotal_F-Ttotal_R[/tex], right?

Yes


1effect said:
But, in eq(8) you are calculating:

[tex]Ttotal_F-T_R_2[/tex], unless it is another typo?


[tex]Ttotal_F-Ttotal_R = (Eq 1) - (Eq2) - (Eq 3) = T_F - T_{R1} - (T_{R2}-T_{R1}) = T_F - T_{R1} - T_{R2} + T_{R1} = T_F - T_{R2} [/tex]

So

[tex]Ttotal_F-Ttotal_R = Ttotal_F-T_R_2 [/tex]
 
  • #8
kev,

Thank you for the previous clarifications. I hope that I am helping you cleaning up the post.
kev said:
It is interesting to note that the difference in the proper times of the clocks after born-rigid acceleration and before synchronisation (Eq 8) is completely determined by the final velocity and the proper spatial separation and is independent of the rate of acceleration or time taken to transfer from one frame to another.

Now, this is somewhat misleading. The accelerations [tex]a_F[/tex] and [tex]a_R[/tex] do not appear in the final result because of the extra conditions that you set on them (measure the elapsed proper time difference when the clocks have achieved the same speed [tex]v[/tex] while maintaining the same proper separation [tex]L_0[/tex]). This is why [tex]v[/tex] replaces [tex]a_F[/tex] and [tex]a_R[/tex] in the final formula of eq(8)
It is obvious from (Eq 8) that if constant proper separation is maintained the clocks will not remain naturally synchronised.

This is well known, indeed.

It is further conjectured that there is no acceleration scheme that can keep two spatially separated clocks synchronised when transferring the clocks from one inertial reference frame to another.

This is an artifact of the fact that the two clocks will describe different trajectories in space-time, so, when you try to calculate the total elapsed proper time via integration, you may get different results (I don't think proper time is a conservative field :-) )
 
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  • #9
1effect said:
kev,

Thank you for the previous clarifications. I hope that I am helping you cleaning up the post.

As always, constructive criticism is always welcome ;)

1effect said:
Now, this is somewhat misleading. The accelerations [tex]a_F[/tex] and [tex]a_R[/tex] do not appear in the final result because of the extra conditions that you set on them (measure the elapsed proper time difference when the clocks have achieved the same speed [tex]v[/tex] while maintaining the same proper separation [tex]L_0[/tex]). This is why [tex]v[/tex] replaces [tex]a_F[/tex] and [tex]a_R[/tex] in the final formula of eq(8)

Accelerating while maintaining constant proper separation is the definition of born-rigid acceleration which is probably the most used acceleration method in discussions of accelerating rockets. It is admittedly an ideal situation, that is probably not often found in nature except as an approximation. The result that clocks go out of synchronisation under ideal born-rigid acceleration is not obvious to everyone.

As far as I can tell the equation I derived in post #1 is correct but unfortunately (for me) I have found a counter example to my own conjecture that I added to the end of the post. “It is further conjectured that there is no acceleration scheme that can keep two spatially separated clocks synchronised when transferring the clocks from one inertial reference frame to another. ( peh! :P) I have found that if we allow for the propagation delay of the acceleration impulse along the length of a rear engined rocket and allow the rocket to compress well beyond its natural length contracted length then it IS possible to find an acceleration pattern that keeps the clocks synchronised. This acceleration pattern allows the clock at the nose of the rocket to follow a longer path through space-time and time dilate to a lesser extent than the rear clock. In the attached diagram the front of the rocket does not start accelerating until coordinate time t2 which is later than the coordinate time t1 when the rear of rocket has finished accelerating. This is because of the minimum time for a signal traveling at light speed to propagate from the rear to the front. In practice this delay would probably be even longer if the impulse wave propagates through the material at the speed of sound.
 

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  • #10
kev said:
As always, constructive criticism is always welcome ;)
Accelerating while maintaining constant proper separation is the definition of born-rigid acceleration which is probably the most used acceleration method used in discussions of accelerating rockets. It is admittedly an ideal situation that is probably not often found in nature except as an approximation. The result that clocks go out of synchronisation under ideal born-rigid acceleration is not obvious to everyone.

Thank you, I know very well what Born-rigid motion means. I was commenting about why [tex]a_R[/tex] and [tex]a_F[/tex] do not show in eq(8). Speaking of eq(8), I did not redo your calculations but the fraction [tex]\frac{L_0 v}{c^2}[/tex] looks very suspect since the result is made up of irrational expressions (square roots and sinh). The only way you may arrive to the rational term is if you did some approximations.

As far as I can tell the equation I derived in post #1 is correct but unfortunately (for me) I have found a counter example to my own conjecture that I added to the end of the post. “It is further conjectured that there is no acceleration scheme that can keep two spatially separated clocks synchronised when transferring the clocks from one inertial reference frame to another. ( peh! :P) I have found that if we allow for the propagation delay of the acceleration impulse along the length of a rear engined rocket and allow the rocket to compress well beyond its natural length contracted length then it IS possible to find an acceleration pattern that keeps the clocks synchronised.

You may want to double-check eq (8), it may not be correct.
 
  • #11
please clarify a few points for me

Hi Kev, Some readers are clued up, e.g. "
1effect said:
Thank you, I know very well what Born-rigid motion means."

But, forgive my ignorance, I am not familiar with the term born-rigid. Does it mean that the clocks are held mounted in gimballs on a beam the length of which is regulated by some clever mechanism? If so, by what criterion would the mechanism decide what to do? Or some other mounting? Please explain for me in simple terms what is meant.

It seems that in an accelerated rocket of finite length, there would be ambiguity about how it should report its own time? The front clock or the back one?

Presumably you are talking about two clocks, front and back, of infinitesimal size, perhaps atomic fountain clocks? Are atoms really infinitesimally small? I think they have finite-diameter electron orbitals? There seems to be an incurable physical difference between the accelerated rocket situation and the gravity field situation: atoms in free fall at the moment of rest relative to the bulk of the fountain clock at the top of the fountain trajectory are not affected by the acceleration of the rocket, but they are still affected by the gravitational field that might in principle cause hyperhyperfine line splitting. Do they always agree with the spherical light clock of A.D. Fokker (1956)? That has a finite diameter that might well affect its performance? According to textbooks of differential geometry, a spherical surface cannot be bent without buckling. Would that still apply to Fokker spherical light clocks in an accelerated rocket? In a gravitational field? Would an atomic fountain clock in a rocket accelerated hard enough to bring the finite diameter of atomic electron orbitals into play still be an ideal clock? Could we use several Fokker clocks and extrapolate to infinitesimal size for our registered read-out? Is it a waste of effort to try to find a preferred ideal clock for accelerated motion?



Christopher
 
  • #12
chjoaygame said:
Hi Kev, Some readers are clued up, e.g. "
1effect said:
Thank you, I know very well what Born-rigid motion means."

But, forgive my ignorance, I am not familiar with the term born-rigid. Does it mean that the clocks are held mounted in gimballs on a beam the length of which is regulated by some clever mechanism? If so, by what criterion would the mechanism decide what to do? Or some other mounting? Please explain for me in simple terms what is meant.
I knew 1effect knew what Born-rigid motion was by I simply restated it for the benefit of other readers that may not. A fairly formal description of Born-rigid motion is given here http://www.mathpages.com/home/kmath422/kmath422.htm.

My informal description would be a method of gently accelerating a rod so that, to observers on the rod, it maintains the same constant proper length that they measured before it accelerated. To an observer on the ground that watched the rod accelerating away, the rod would appear to be continually length contracting as the rod's velocity relative to him increased. The rod's length would not be exactly [itex]L ' = L \sqrt{1-v^2/c^2}[/itex] by his measurements because the back of the rod is accelerating faster than the front of the rod at any given instant so v is not clearly defined at any given instant.

chjoaygame said:
It seems that in an accelerated rocket of finite length, there would be ambiguity about how it should report its own time? The front clock or the back one?
Yes. Under some acceleration patterns there are ambiguities as to which clock to refer to and difficulties in syncronising clocks. The digital output of some of the clocks would have to be compensated so that they appear to run at the same rate. The same problem occurs when trying to syncronise clocks at the top and bottom of a very high tower in a gravity field. The higher clock would be running at a higher rate. If the higher clock sent signals at one second intervals to the lower clock they would appear to be the signals would appear to be arriving faster than once per second to an observer at the bottom referring to the lower clock.

chjoaygame said:
Presumably you are talking about two clocks, front and back, of infinitesimal size,
Yes, it is idealistic situation.

chjoaygame said:
perhaps atomic fountain clocks? Are atoms really infinitesimally small?

No, atoms are quite big on the Planck scale. The Planck length is 1.6 x [itex]10^{-35}[/itex] m. A Hydrogen atom is about 1 x [itex]10^{-11}[/itex] m.

chjoaygame said:
I think they have finite-diameter electron orbitals? There seems to be an incurable physical difference between the accelerated rocket situation and the gravity field situation: atoms in free fall at the moment of rest relative to the bulk of the fountain clock at the top of the fountain trajectory are not affected by the acceleration of the rocket, but they are still affected by the gravitational field that might in principle cause hyperhyperfine line splitting. Do they always agree with the spherical light clock of A.D. Fokker (1956)? That has a finite diameter that might well affect its performance? According to textbooks of differential geometry, a spherical surface cannot be bent without buckling. Would that still apply to Fokker spherical light clocks in an accelerated rocket? In a gravitational field? Would an atomic fountain clock in a rocket accelerated hard enough to bring the finite diameter of atomic electron orbitals into play still be an ideal clock? Could we use several Fokker clocks and extrapolate to infinitesimal size for our registered read-out? Is it a waste of effort to try to find a preferred ideal clock for accelerated motion?



Christopher

Well, I think you are the better expert on types of clocks than I am ;) All I can say is that I have confidence that in inertial (constant velocity) situations all types of clocks from light clocks to spring clocks to biological clocks behave in a consistent way in Special Relativity whatever their size. However there may be differences in the ways clocks behave under acceleration and (possibly) smaller is better. Post #1 shows that Born-rigid motion is not a good method of acceleration if you want to keep clocks naturally syncronised. Post #9 shows that a rocket with a single rear engine, a rod blasted out of a cannon and a mass ejected out of an exploding supernova will maintain syncronisation of accelerated clocks better than artificial Born-rigid motion.
 
  • #13
1effect said:
Thank you, I know very well what Born-rigid motion means. I was commenting about why [tex]a_R[/tex] and [tex]a_F[/tex] do not show in eq(8). Speaking of eq(8), I did not redo your calculations but the fraction [tex]\frac{L_0 v}{c^2}[/tex] looks very suspect since the result is made up of irrational expressions (square roots and sinh). The only way you may arrive to the rational term is if you did some approximations.

You may want to double-check eq (8), it may not be correct.

Irrational numbers are simply numbers that cannot be expressed as a ratio of whole natural numbers. I assume you actually meant transcendental expressions which sinh is but square is not. As far as the expression contained within the sinh function is concerned I only did straight substitutions of equivalent values into the function but otherwise performed no mathematical operations on it.

Square roots are not transcendental functions but they can present problems due to having real or imaginary roots. As long as c is greater than zero and v is less than c there are not too many problems in handling them here.

The expression [tex]\frac{L_0 v}{c^2}[/tex] comes directly from substitutions into

(Eq 3) [tex]T_{R2} - T_{R1} = (t_f - t_r)\sqrt{1-v^2/c^2}[/tex]

which does not contain the transcendental sinh function.

By re-writing the rhs of (Eq 3) as

(Eq 11) [tex] \left(t_f\sqrt{1-v^2/c^2} - t_r\sqrt{1-v^2/c^2}\right)[/tex]

and substituting [tex]t={v \over a\sqrt{1-v^2/c^2}[/tex] into (Eq 11) we get

(Eq 12) [tex] {v \over a_F} - {v \over a_R} [/tex]

then substituting [tex] a_F = {c^2a_R \over (L_0 a_R +c^2)}[/tex] into (Eq 12) we get

(Eq 13) [tex] {v(L_0a_R+c^2) \over c^2a_r} - {v \over a_R} = {vL_0a_r+vc^2-vc^2 \over c^2a_R} = {L_0 v \over c^2}[/tex]

Nothing too dodgy there I think.
 
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  • #14
kev said:
Irrational numbers are simply numbers that cannot be expressed as a ratio of whole natural numbers. I assume you actually meant transcendental expressions which sinh is but square is not. As far as the expression contained within the sinh function is concerned I only did straight substitutions of equivalent values into the function but otherwise performed no mathematical operations on it.

Square roots are not transcendental functions but they can present problems due to having real or imaginary roots. As long as c is greater than zero and v is less than c there are not too many problems in handling them here.

The expression [tex]\frac{L_0 v}{c^2}[/tex] comes directly from substitutions into

(Eq 3) [tex]T_{R2} - T_{R1} = (t_f - t_r)\sqrt{1-v^2/c^2}[/tex]

which does not contain the transcendental sinh function.

By re-writing the rhs of (Eq 3) as

(Eq 11) [tex] \left(t_f\sqrt{1-v^2/c^2} - t_r\sqrt{1-v^2/c^2}\right)[/tex]

and substituting [tex]t={v \over a\sqrt{1-v^2/c^2}[/tex] into (Eq 11) we get

(Eq 12) [tex] {v \over a_F} - {v \over a_R} [/tex]

then substituting [tex] a_F = {c^2a_R \over (L_0 a_R +c^2)}[/tex] into (Eq 12) we get

(Eq 13) [tex] {v(L_0a_R+c^2) \over c^2a_r} - {v \over a_R} = {vL_0a_r+vc^2-vc^2 \over c^2a_R} = {L_0 v \over c^2}[/tex]

Nothing too dodgy there I think.

Thank you, this explains very well my point about the solution being independent of [tex]a_F[/tex] and [tex]a_R[/tex] due to imposing that:
-proper separation [tex]L_0[/tex] is maintained
-both clocks arrive to the same terminal speed [tex]v[/tex]
 
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  • #15
reply kev on Proper time of accelerated clocks

Hi Kev.

Thank you for your reply.

Thank you for the link to the article on Born-rigidity. It might even perhaps be said at one point to support Aristotle's much ridiculed notion about inertia! I will have to think about it.

You write (with a slight editorial tidy-up by me): #If the higher clock sent signals at one second intervals to the lower clock they would appear to be arriving more than once per second to an observer at the bottom referring to the lower clock.# This is the most concisely commonsensical and perspicuously meaningful plain English statement I have read about this. Thank you. Though this comment of yours has a clear meaning, the phenomenon it describes is still baffling. Would it concomitantly be the case that #If the lower clock sent signals at one second intervals to the higher clock they would appear to be arriving less than once per second to an observer at the top referring to the higher clock.#? I think so.

Presumably we are talking about light pulses. A light pulse can vary in its frequency, its wavelength, its speed, its duration, and its energy, its polarisation, and its coherence. Whence come the extra pulses, and whither go the missing ones? To or from the past, the future, a storage place part way up the tower, the very matter at the top or bottom of the tower? How do the pulses change on their way? If this went on for long enough, what would happen: would it mean that the light pulses on the way up were supplied by actually eroding the Earth at the bottom and sending it up to the top where their energy was stored, till there was no more Earth left at the bottom, and the tower got very very top heavy? Or that the top of the tower would be eroded by the need to supply energy for the downgoing pulses until there was no more top of the tower? Does conservation of mass-energy apply here? Does this fit with the notion that photons are particles that can be counted as they travel? Would the height of the tower gradually change because of all this? In answers to these questions, what is a priori or ex cathedra postulate, and what is observed or observable fact?

How about sending not light pulses, but rather atoms of ponderable matter, at speeds less than light speed? Same questions, except for different degrees of freedom for atoms.

Let's leave the clock design and construction problem to another day.



Christopher
 
  • #16
Hi Christopher.

chjoaygame said:
... You write (with a slight editorial tidy-up by me): #If the higher clock sent signals at one second intervals to the lower clock they would appear to be arriving more than once per second to an observer at the bottom referring to the lower clock.# This is the most concisely commonsensical and perspicuously meaningful plain English statement I have read about this. Thank you. Though this comment of yours has a clear meaning, the phenomenon it describes is still baffling. Would it concomitantly be the case that #If the lower clock sent signals at one second intervals to the higher clock they would appear to be arriving less than once per second to an observer at the top referring to the higher clock.#? I think so.

Yes


chjoaygame said:
Presumably we are talking about light pulses. A light pulse can vary in its frequency, its wavelength, its speed, its duration, and its energy, its polarisation, and its coherence. Whence come the extra pulses, and whither go the missing ones? To or from the past, the future, a storage place part way up the tower, the very matter at the top or bottom of the tower? How do the pulses change on their way? If this went on for long enough, what would happen: would it mean that the light pulses on the way up were supplied by actually eroding the Earth at the bottom and sending it up to the top where their energy was stored, till there was no more Earth left at the bottom, and the tower got very very top heavy? Or that the top of the tower would be eroded by the need to supply energy for the downgoing pulses until there was no more top of the tower? Does conservation of mass-energy apply here? Does this fit with the notion that photons are particles that can be counted as they travel? Would the height of the tower gradually change because of all this? In answers to these questions, what is a priori or ex cathedra postulate, and what is observed or observable fact?

Observable facts:

(a) The Pound Rebka Harvard Tower experiment. The frequency of waves sent up a tower was observer to be reduced by a detector at the top of the tower. Conversely signals sent down the tower were seen to increase in frequency.

(b) Atmospheric muon observations. The half life of muons is known to be too short for muons created at the top of the Earth's atmosphere to live long enough to make to it to sea level. However far too many muons are detected at sea level. This is accounted for by time dilation extending the effective life of the muons long enough for them to make the complete journey.

(c) Many particle laboratories routinely measure the half life of transient particles as extended by the time dilation factor when the particles are moving at relativistic speeds or when stored in cyclotrons that keep the particles accelerating in circles.

Time dilation is routinely observed in laboratories every day all over the world. I would be surprised if there was a single employed physicist alive today that doubted the validity of time dilation.

However, some would argue that experiment (a) does not directly show that the lower clock is running slower than the top clock. They say the wavelength of the photon is continually stretching as the photon climbs up the gravity well (and the frequency of the photon is slowing down and therefore the photon is losing energy). Where has this energy gone that the photon has lost? In classical physics an object thrown upwards loses kinetic energy and gains potential energy, and this potential energy is stored in the gravitational field. In general relativity there isn't a gravitational field that can store potential energy. A distant observer watching the photon climbing up the gravitational well would see the coordinate speed of the photon as apparently increasing so he could argue that the loss of the photon's energy as calculated by Energy=h(frequency) is compensated by the apparent increase in the photon's velocity. Energy=h(frequency) can expressed as Energy = hc/(wavelength). In this view the loss of energy due to increased wavelength of the photon, is compensating by the apparent increase in c as measured by the distant observer. However this is a very controversial view and it should always be stressed that c is always measured as 299792458 m/s by any local observer.

chjoaygame said:
How about sending not light pulses, but rather atoms of ponderable matter, at speeds less than light speed? Same questions, except for different degrees of freedom for atoms...

Personally, I have no doubt that atoms sent down the tower at a frequency of once per second (as measured by a clock at the top) will be seen to be arriving at intervals of less than one second, as measured by a clock at the base (and vice versa going the other way).

Others may differ.

P.S. A red light shone from the top of a sufficiently high tower would appear red to an observer at the base and a blue light shone from the base would appear red to an observer at the top of the tower. I think most people would agree with that.
 
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  • #17
kev said:
Hi Christopher.


(a) The Pound Rebka Harvard Tower experiment. The frequency of waves sent up a tower was observer to be reduced by a detector at the top of the tower. Conversely signals sent down the tower were seen to increase in frequency.

You mean the other way around, right? :-)
 
  • #18
1effect said:
kev said:
(a) The Pound Rebka Harvard Tower experiment. The frequency of waves sent up a tower was observer to be reduced by a detector at the top of the tower. Conversely signals sent down the tower were seen to increase in frequency.

You mean the other way around, right? :-)

Quote from that link: "The effect is very small but measurable on Earth using the Mossbauer effect and was first observed in the Pound-Rebka experiment.[32] However, it is significant near a black hole, and as an object approaches the event horizon the red shift becomes infinite." Increasing red shift is synonomous with increasing wavelength which is the same thing as decreasing frequency.

Quote from this link http://hyperphysics.phy-astr.gsu.edu/hbase/relativ/gratim.html#c2

"the gain in energy for a photon which falls distance h is ..." gain in energy for a falling photon is the same as saying the frequency of the falling photon is increasing.


From this wikipedia article on gravitational redshift: http://en.wikipedia.org/wiki/Gravitational_redshift

" In physics, light or other forms of electromagnetic radiation of a certain wavelength originating from a source placed in a region of stronger gravitational field (and which could be said to have climbed "uphill" out of a gravity well) will be found to be of longer wavelength when received by an observer in a region of weaker gravitational field. "

Longer wavelength = reduced frequency.

So no, not the other way round.
 
  • #19
kev said:
Quote from that link: "The effect is very small but measurable on Earth using the Mossbauer effect and was first observed in the Pound-Rebka experiment.[32] However, it is significant near a black hole, and as an object approaches the event horizon the red shift becomes infinite." Increasing red shift is synonomous with increasing wavelength which is the same thing as decreasing frequency.

Quote from this link http://hyperphysics.phy-astr.gsu.edu/hbase/relativ/gratim.html#c2

"the gain in energy for a photon which falls distance h is ..." gain in energy for a falling photon is the same as saying the frequency of the falling photon is increasing.From this wikipedia article on gravitational redshift: http://en.wikipedia.org/wiki/Gravitational_redshift

" In physics, light or other forms of electromagnetic radiation of a certain wavelength originating from a source placed in a region of stronger gravitational field (and which could be said to have climbed "uphill" out of a gravity well) will be found to be of longer wavelength when received by an observer in a region of weaker gravitational field. "

Longer wavelength = reduced frequency.

So no, not the other way round.
"Likewise, gravitational blue shifts are associated with light emitted from a source residing within a weaker gravitational field (i.e. , top of the tower) observed within a stronger gravitational field (i.e. bottom of the tower), while gravitational redshifting implies the opposite conditions."

You are right, we are saying the same thing, just in a reverse order. My bad.
 
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1. What is proper time and how is it different from coordinate time?

Proper time is the time measured by a clock that is at rest with respect to the events being measured. It is different from coordinate time, which is the time measured by a clock that is moving with respect to the events. Proper time takes into account the effects of time dilation due to relative motion, while coordinate time does not.

2. How does acceleration affect the proper time of a clock?

According to Einstein's theory of relativity, acceleration affects the proper time of a clock by causing time dilation. This means that the faster a clock is accelerating, the slower it will appear to be ticking when compared to a clock at rest. This effect becomes more significant as the acceleration increases.

3. Can the proper time of a clock ever be greater than the coordinate time?

Yes, the proper time of a clock can be greater than the coordinate time, especially in cases of extreme acceleration. This is because the faster a clock is accelerating, the slower it will appear to be ticking. As a result, the proper time measured by the clock will be longer than the coordinate time.

4. How does gravitational time dilation affect the proper time of a clock?

Gravitational time dilation refers to the effect of gravity on the passage of time. In the presence of a strong gravitational field, time appears to pass slower. This means that the proper time of a clock in a strong gravitational field will be longer than the proper time of a clock in a weaker gravitational field. This is due to the curvature of spacetime caused by the presence of mass.

5. Is the concept of proper time important in modern physics?

Yes, the concept of proper time is crucial in modern physics, particularly in the fields of relativity and quantum mechanics. It is essential in understanding the effects of time dilation and the concept of spacetime. Proper time is also used in calculations and experiments involving high speeds and strong gravitational fields, such as in particle accelerators and GPS systems.

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