Time dilation why or how, Special Relativity causes

In summary, the question of why or how time slows as you accelerate a time tracking device is currently driving me nuts. I was hoping someone might have the answer as to why or how time slows as it measured during acceleration.
  • #71
Sugdub said:
It took me some time until I could formulate an answer to this. Indeed I have a strong “aversion” to wordings such as “proper time, proper length, clock slowing down” or “running slow”, being “late”... and several more. On second thoughts, I think these wordings are remnants of an ontology - the former Newtonian ontology - which contradicts the SR formalism.

You're mixing up different things in your list of phrases. "Proper time" and "proper length" are definitely SR concepts (and they extend to GR). They are not "remnants of a Newtonian ontology" at all.

For me the “proper time” and “proper period” do not belong to the ontological domain: actually these wordings point to amounts of a coordinate quantity. It can't be true that clocks measure amounts of “time” and neither of “proper time”.

I don't think what you're saying is true, at all. Clocks certainly do measure proper time, and proper time is certainly a fundamental concept of SR (and also GR).
 
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  • #72
Sugdub said:
Whereas this effectively makes the “proper time” invariant in value, it remains in essence a representation-dependent concept, an amount of “time”, an amount of a coordinate quantity.

No, this is not correct. Proper time is a geometric quantity: it is the length along a given timelike curve between two events. It depends on the curve (as well as the chosen events), but it doesn't depend at all on the "representation" we choose for the curve (I'm not sure exactly what you mean by "representation", but I think you mean something like coordinates or parameterization, and proper time doesn't depend on those).

Sugdub said:
Moreover, its definition refers to a specific frame, the rest frame of the clock

No, it doesn't. You are using the wrong definition; see above for the correct, geometric one, which makes no mention of frames at all.

Sugdub said:
I think there is no alternative but accepting that a clock measures amounts of "space-time".

If by "amounts of spacetime" you simply mean "the geometric length along a particular timelike curve", then that is what a clock measures. See above.
 
  • #73
Sugdub said:
...It can't be true any more that clocks and rulers respectively measure amounts of “time” and amounts of “space”. The ontology must change. So what do they measure?
According to (peculiar) presentations of the SR theory often displayed in PF, a clock is now assigned a “proper period” and it measures amounts of “proper time”. The value of the “proper time” equals the extremal value taken by the “time” component of the “space-time” interval between two events in the clock's worldline...
Thank you for using the correct term Proper Time. You now need to respond to my questions in post #57 regarding Proper Length and how the length contraction formula is related "the space component of the same space-time interval".
 
  • #74
Sugdub said:
Indeed I have a strong “aversion” to wordings such as “proper time, proper length, clock slowing down” or “running slow”, being “late”... and several more. On second thoughts, I think these wordings are remnants of an ontology - the former Newtonian ontology - which contradicts the SR formalism.
I appreciate this response. It is actually relevant to the use of the word "metaphysical". Thank you for that.

Two general thoughts on this:

First, I don't think that an ontology can contradict a formalism even in principle. You always have the flexibility, in any formalism, to label x as "real" and y as "not-real". So the primary question of ontology is formalism-neutral. All that you can talk about is what a given formalism predicts for the outcome of a given experiment. The formalism cannot tell you which parts are "real". Furthermore, you can change formalisms quite easily, and I suspect that very few people believe that in changing a formalism you have changed reality. For example, you can use the Newtonian formalism or the Lagrangian formalism or the Hamiltonian formalism to work the same problem in classical mechanics.

Second, I agree with you completely that many of the wordings are shamelessly taken from Newtonian physics. However, as I said above, there is no ontology defined by the Newtonian formalism either. You are still free to classify things as "real" or "not real" even in Newtonian physics. Furthermore, it is well-known that the same word can have different meanings in different contexts. If you are going to classify a defined term in a theory then you have to use that theory's definition of the term, not some other theory. This does indeed make it more difficult for students to learn.

Sugdub said:
Whereas this effectively makes the “proper time” invariant in value, it remains in essence a representation-dependent concept, an amount of “time”, an amount of a coordinate quantity. Moreover, its definition refers to a specific frame, the rest frame of the clock, and this contradicts the fundamental principle of SR insofar there is a privileged frame.
This is simply incorrect. Proper time is not "an amount of a coordinate quantity". While it is true that you can always build a coordinate system around a given clock's proper time, that does not make the proper time "representation-dependent".

Your same objection, were it correct, would also apply to the Newtonian concept of the length of a ruler which you correctly described above as being independent. You can also build a Newtonian coordinate system around a ruler, but that does not make the concept of the ruler's length a coordinate-dependent quantity.

Sugdub said:
For me the “proper time” and “proper period” do not belong to the ontological domain: actually these wordings point to amounts of a coordinate quantity.
The solution is simply for you to understand the actual definition as understood by the physics community.

Sugdub said:
I think there is no alternative but accepting that a clock measures amounts of "space-time".
Physicists clearly already accept that, and that is precisely what they mean when they use the word "proper time".
 
  • #75
ghwellsjr said:
Thank you for using the correct term Proper Time. You now need to respond to my questions in post #57 regarding Proper Length and how the length contraction formula is related "the space component of the same space-time interval".
You are perfectly right. Time dilation and length contraction relate to different, exclusive classes of space-time intervals. Thanks for this.
 
  • #76
DaleSpam said:
... Physicists clearly already accept that, and that is precisely what they mean when they use the word "proper time".
Hmmm... Let me express some doubts. Considering the responses proposed in #71, 72, 73 and 74, it appears there is no consensus about the actual meaning of the wording “proper time”. Does it refer ...
1- to an amount of “space-time” (here I mean the compound quantity S which is mathematically described by all SR lectures using a 4-coordinates vector in a manifold, one of these coordinates being “time” and the three other being “space”)?
2- to an amount of “time” (e.g. the “time” component of a space-time interval)?
3- to an amount of “space” (e.g. the “length” of a curve)?
4- ?
Looking at #71, I interpret this as option 2.
In #72, although the spelling looks close to option 3, I think the proposed definition can be better understood alongside option 1 subject to replacing “length” (which is too much “space”-related) with “measure”. Hence the question I raised in #53 about the nature of the “ageing” quantity, but no clear answer so far.
According to #73, it would seem that option 2 is accepted.
Finally the last statement in #74 seems to agree with option 1.

I have made clear that I consider option 1 is the only one viable: a clock measures the amount of “space-time” “crossed” along a “path” linking a pair of time-like physical events. An inertial clock will deliver the lowest value since it travels along a geodesic curve. A non-inertial clock will deliver an higher value. The value of S can by defined as the integral over the curved path of the dS element which defines the measure of an infinitesimal space-time interval. It is a compound quantity which contributing coordinates are “time” and “space” related, however it is clear that contrary to its coordinates, dS is frame-invariant whilst being path-dependent. Both characteristics are required in order to account for the objective nature of the outcome of a physical measurement process involving a clock, whilst ensuring the varaibility of this outcome in response to any physical constraint applied to the clock which forces it to deviate from a geodesic path. This is why I suggested that a clock measures amounts of “space-time”. In the rest frame of an inertial clock, only the “time” coordinate contributes to the value of dS. However, due to the equivalence of all inertial frames, that does not imply that what gets measured by a clock is an amount of “time”: although the numerical values are equal, the ontological status of the “time” and “space-time” concepts is different.
I'm afraid I can't go further until what is referred to under “proper time” gets clarified.
 
  • #77
Sugdub said:
ghwellsjr said:
Thank you for using the correct term Proper Time. You now need to respond to my questions in post #57 regarding Proper Length and how the length contraction formula is related "the space component of the same space-time interval".
You are perfectly right. Time dilation and length contraction relate to different, exclusive classes of space-time intervals. Thanks for this.
I'm perfectly right about what? I said in post #57, "I think you are getting yourself into trouble by focusing on the space-time interval" and yet you continue to do so. It's no wonder you can't figure out what Proper Time is and I haven't seen how you relate Proper Length to the spacetime interval. If you would explain your concept of Proper Length, I think you would see that your notions are misguided.
 
  • #78
Sugdub said:
Hmmm... Let me express some doubts. Considering the responses proposed in #71, 72, 73 and 74, it appears there is no consensus about the actual meaning of the wording “proper time”. Does it refer ...
1- to an amount of “space-time” (here I mean the compound quantity S which is mathematically described by all SR lectures using a 4-coordinates vector in a manifold, one of these coordinates being “time” and the three other being “space”)?
2- to an amount of “time” (e.g. the “time” component of a space-time interval)?
3- to an amount of “space” (e.g. the “length” of a curve)?

There is no ambiguity about the definition of "proper time". It's given by: [itex]\tau = \int \sqrt{|g_{\mu \nu} \frac{dx^\mu}{d\lambda} \frac{dx^\nu}{d\lambda}|} d\lambda[/itex] for a parametrized path [itex]\mathcal{P}(\lambda)[/itex] described in coordinates by [itex]x^\mu(\lambda)[/itex]. The physical meaning is that if the parametrized path is the path taken by an idealized clock, then [itex]\tau[/itex] is the elapsed time on that clock. There is complete consensus about these two claims.

The integral giving [itex]\tau[/itex] makes use of coordinates, but the value is independent of which coordinates you use. You could state the definition more abstractly by:

[itex]\tau = \int \sqrt{g(U,U)} d\lambda[/itex]

where [itex]U[/itex] is the tangent vector to the path [itex]\mathcal{P}(\lambda)[/itex]. But to actually compute that integral, you have to choose a coordinate system.
 
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  • #79
Sugdub said:
I have made clear that I consider option 1 is the only one viable: a clock measures the amount of “space-time” “crossed” along a “path” linking a pair of time-like physical events. An inertial clock will deliver the lowest value since it travels along a geodesic curve. A non-inertial clock will deliver an higher value.

You've got that exactly backwards. An inertial path has the greatest value for proper time (at least in SR).
 
  • #80
Sugdub said:
Let me express some doubts. Considering the responses proposed in #71, 72, 73 and 74, it appears there is no consensus about the actual meaning of the wording “proper time”.
Looking at the responses in 71, 72, 73, and 74 it appears that there is complete consensus about the meaning of "proper time". Your doubts seem to be based on a simple misunderstanding on your part.

That is not particularly surprising, all of us are trying to express the math in English, and many things get garbled in the translation. However, the meaning is clear in the math. Please review post 78. To see the complete link between your post 76 and stevendaryl's post 78 please note that ##ds^2=g_{\mu\nu} dx^{\mu} dx^{\nu}##.

There is no ambiguity, proper time is an invariant measure of the spacetime interval along a timelike path. That is what clocks measure.
 
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  • #81
DaleSpam said:
Looking at the responses in 71, 72, 73, and 74 it appears that there is complete consensus about the meaning of "proper time"...proper time is an invariant measure of the spacetime distance along a timelike path. That is what clocks measure.

Since I made one of the posts under discussion, I'll chime in here as well to say I agree with all of this.
 
  • #82
Einstein Devotee said:
I understand the theory of special relativity and the mathematics which support it. I even understand that the time dilation has been proven. Therefore I am going to ask a question which on first blush may appear that I disagree with it but that is not the case. The question I can not seem to find an answer to anywhere is the why or how time dilation occurs? I am not seeking an example of where and when it occurs but the cause of time slowing as you accelerate the time tracking device.

That question is currently driving me nuts and I was hoping someone might have the answer as to why or how time slows as it measured during acceleration...

Ask why the grass is green in Special Relativity...get a comprehensive explanation of Global Warming and Biological Evolution, but not why the grass is green in Special Relativity.
The answer to your question lies within Einstein's second postulate as it applies to the light clock (http://galileoandeinstein.physics.virginia.edu/more_stuff/flashlets/lightclock.swf). At rest, the light travels between a fixed path distance between the mirrors causing the light clock to tick. In motion, the light must traverse a greater path distance between the mirrors, due to motion of the clock as a result of simple geometry, thereby taking a greater amount of time to traverse the path between the mirrors and therefore results in slower clock ticks. For any specified path distance between two points in a rest frame, the same path ALWAYS has a different distance when this system is placed in uniform motion. Greater path distances is exactly why clocks slow in inertial frames...period!

For a more comprehensive explanation, see; <<link deleted>>
 
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  • #83
DaleSpam said:
Looking at the responses in 71, 72, 73, and 74 it appears that there is complete consensus about the meaning of "proper time". Your doubts seem to be based on a simple misunderstanding on your part.
That is not particularly surprising, all of us are trying to express the math in English, and many things get garbled in the translation. However, the meaning is clear in the math. Please review post 78. To see the complete link between your post 76 and stevendaryl's post 78 please note that ##ds^2=g_{\mu\nu} dx^{\mu} dx^{\nu}##.
There is no ambiguity, proper time is an invariant measure of the spacetime interval along a timelike path. That is what clocks measure.

I thank you and stevendaryl for your inputs. Your confirmation that my proposal is fully backed-up by the most generic mathematical formalism of the SR and GR theories is a major step.
Due to the logical precedence of the “space-time” concept over its time and space coordinate components, I felt it was no longer possible to consider that what gets measured by a clock is of a “time” nature. Therefore I criticised the semantics of the language used by physicists, in particular wordings such as “proper time” and “elapsed time” since their intuitive meaning refers to amounts of a “time” nature, whereas the mathematical concept corresponding to what gets actually measured deals with amounts of space-time, i.e. the measure of a space-time interval.
It is amazing to read that the misunderstanding is only on my part. Where has it been explained that a clock measures amounts of the S quantity, i.e. amounts of “space-time”? I can't remember any presentation of SR, any lecture heading in this direction. For me the wording “proper time” is not only highly misleading, it is symptomatic of a misconception about what gets actually measured: why did physicists introduce this wording whereas “space-time” was already available and fully appropriate? The “major step” I refer to above precisely consists in getting rid of this misconception.
But never mind. Let's try and secure our common understanding. I referred to “a pair of time-like physical events”. This is certainly not correct: “time-like” relates to the pair, not to individual events. So a better wording would be “a time-like pair of physical events”, with “time-like” indicating that there exists an inertial frame of reference in which the physical events at stake are represented as being co-located. Hopefully this is what you call a “timelike path” and the following statement will be backed-up: “ A clock delivers an invariant measure of the space-time interval along a path connecting a time-like pair of physical events”. Please let me know.
Let's now come back to my post #53 and consider the “ageing” of the twins along their respective journeys. There is absolutely no doubt that the word “ageing” has been chosen because it designates what we usually consider being an increase in the age of the twins, hence a “time” interval. Now we must acknowledge that “ageing” actually designates an increase in S, an amount of space-time, the measure of a space-time interval. Subtracting S' from S is certainly possible, but this so-called “difference in ageing” can in no way be considered as a difference in the age of the twins. How could that lead to a statement whereby one of the twins comes back “younger” than the other? The only way would be to isolate the “time” components of S and S' respectively and to subtract one from the other... but first, one would need to ascertain that it is physically meaningful to breakdown S and S' onto the same base of the same manifold (I've never seen any consideration about this) and second, one would have to ascertain that the difference between both “time” components is frame-invariant (which I believe is not true: only the difference between S and S' is frame-invariant).
Both twins have a different life history life history. A comparison can certainly be drawn, but no objective qualification of the difference can be made in terms of a frame-invariant time interval. So a statement whereby one of the twins comes back “younger” or “ages less” propagates an erroneous conclusion.
The same goes for clocks “slowing down” or “being late”. Of its own, the experiment cannot sort out whether the non-inertial clock changes behaviour or whether it follows a different path in space-time. However your inputs show that semantic characterisations accounting for a “time” interval are necessarily frame-variant. Therefore I think such expressions should be firmly rejected.
 
  • #84
Sugdub said:
the mathematical concept corresponding to what gets actually measured deals with amounts of space-time, i.e. the measure of a space-time interval.

Sugdub said:
It is amazing to read that the misunderstanding is only on my part. Where has it been explained that a clock measures amounts of the S quantity, i.e. amounts of “space-time”?

You mean no presentation of SR that you have read has used the term "spacetime interval"? That seems hard to believe. In the text I learned SR from (Taylor & Wheeler's Spacetime Physics), the term "spacetime interval" is all over the place.

That said, this "S quantity" you refer to is not well-defined as it stands. What does "amount of spacetime" mean? Spacetime is a 4-dimensional geometric object. Does the "amount" of it refer to the "size" of a 4-dimensional subset? Of a 3-dimensional hypersurface? A 2-dimensional surface? A 1-dimensional curve? All of these are conceptually distinct, so you can't just use one term, "amount of spacetime", to refer to all of them. That's why physicists have different terms for these different things. See below.

Sugdub said:
For me the wording “proper time” is not only highly misleading, it is symptomatic of a misconception about what gets actually measured: why did physicists introduce this wording whereas “space-time” was already available and fully appropriate?

Because "spacetime" describes the 4-dimensional geometric object, and "proper time" describes the arc length along a one-dimensional timelike curve within this 4-dimensional geometric object. They're different things, so it's entirely appropriate to have different terms for them.

Sugdub said:
“ A clock delivers an invariant measure of the space-time interval along a path connecting a time-like pair of physical events”.

Yes (with the appropriate definition of "a time-like pair of events", which you give earlier in the same paragraph. Note that this "space-time interval" is an arc-length along a 1-dimensional curve, as above.

Sugdub said:
There is absolutely no doubt that the word “ageing” has been chosen because it designates what we usually consider being an increase in the age of the twins, hence a “time” interval. Now we must acknowledge that “ageing” actually designates an increase in S, an amount of space-time, the measure of a space-time interval.

They are the same thing; the term "time interval" is just shorthand for "spacetime interval along a timelike curve". Why do you think we call such curves "timelike"? Because you measure arc length along them with a clock, not a ruler.

Sugdub said:
Subtracting S' from S is certainly possible, but this so-called “difference in ageing” can in no way be considered as a difference in the age of the twins.

Yes, it is. You have an incorrect understanding of what the term "time interval" means; see above. With the correct understanding, as given above, S and S' are indeed "time intervals", and subtracting them does give a difference in aging. You don't need to separate out "time components"; in fact you don't even need to define coordinates at all. The difference between S and S' is an invariant physical difference: the physical manifestation of this difference is the difference in age of the twins (as recorded on their clocks, in their biological processes, their experienced time, etc.) when they come back together.

Sugdub said:
The same goes for clocks “slowing down” or “being late”. Of its own, the experiment cannot sort out whether the non-inertial clock changes behaviour or whether it follows a different path in space-time.

Yes, they can; following a different path in spacetime can be measured. The fact that the two twins in the twin paradox follow different paths in spacetime is an invariant physical fact, just like the difference in arc length along those different paths. The measurement is simple: do the two objects (twins, clocks, whatever) stay co-located all the time (i.e., do they pass through exactly the same set of events)? If not, they are following different paths through spacetime.

You appear to be getting hung up on superficial features of the words we use to describe SR in English, instead of looking at the underlying concepts. If you look at the actual math, there is no ambiguity at all; and if you look at how the math gets translated into predictions about physical observables, there is no ambiguity there either.
 
  • #85
Sugdub said:
Due to the logical precedence of the “space-time” concept over its time and space coordinate components, I felt it was no longer possible to consider that what gets measured by a clock is of a “time” nature. Therefore I criticised the semantics of the language used by physicists, in particular wordings such as “proper time” and “elapsed time” since their intuitive ...whether it follows a different path in space-time. However your inputs show that semantic characterisations accounting for a “time” interval are necessarily frame-variant. Therefore I think such expressions should be firmly rejected.

Does the above post mean that clocks measure spacetime, not just time?
 
  • #86
PeterDonis said:
You mean no presentation of SR that you have read has used the term "spacetime interval"? That seems hard to believe. In the text I learned SR from (Taylor & Wheeler's Spacetime Physics), the term "spacetime interval" is all over the place.
No, I mean that I've never seen a statement whereby the measure S of a space-time interval varies depending on the path followed end-to-end, I've never seen a statement whereby what a clock measures is nothing else than S along a definite path. These are things you don't find in presentations of SR easily accessible by non-physicists, or by those having a limited background in maths. When I suggested in a previous post that a clock actually measures S instead of a time quantity, I was really “fishing”.
PeterDonis said:
That said, this "S quantity" you refer to is not well-defined as it stands. What does "amount of spacetime" mean? Spacetime is a 4-dimensional geometric object. Does the "amount" of it refer to the "size" of a 4-dimensional subset? Of a 3-dimensional hypersurface? A 2-dimensional surface? A 1-dimensional curve? All of these are conceptually distinct, so you can't just use one term, "amount of spacetime", to refer to all of them. That's why physicists have different terms for these different things. See below.
This is an excellent comment. Thanks.
PeterDonis said:
Because "spacetime" describes the 4-dimensional geometric object, and "proper time" describes the arc length along a one-dimensional timelike curve within this 4-dimensional geometric object. They're different things, so it's entirely appropriate to have different terms for them.
Yes, I agree to the need for different terms for different things, however the terms must be chosen in a meaningful way. In the Newtonian context, there is no doubt that what a clock measures relates to an interval alongside the time axis. In the SR context, it is no longer the case. Contrary to “time dilation” which describes the variation of an interval alongside the time axis, the curved line which gets measured by a clock is not, in general, alongside the time coordinate axis: hence the importance of using appropriate terms. The common misconception whereby “time dilation” reflects what a clock measures (that is what this thread was initially dealing with) is a recurrent thematic which cannot be eliminated as long as physicists claim that a clock actually measures a time interval.
PeterDonis said:
Yes (with the appropriate definition of "a time-like pair of events", which you give earlier in the same paragraph. Note that this "space-time interval" is an arc-length along a 1-dimensional curve, as above.
Yes, well-done. Please don't forget to mention that in general, this curved line does coincide with the time axis. This is essential.
PeterDonis said:
They are the same thing; the term "time interval" is just shorthand for "spacetime interval along a timelike curve".
No. the curved line is not alongside the time axis. So it is not appropriate to call this a "time interval". I've no problem with the maths definition, but I strongly disagree with the naming.
PeterDonis said:
Why do you think we call such curves "timelike"? Because you measure arc length along them with a clock, not a ruler.
I think my wording whereby there exists a reference frame in which both limiting events are represented as being co-located is better than “because we use a clock”.
PeterDonis said:
Yes, it is. You have an incorrect understanding of what the term "time interval" means; see above.
No, see above. The semantics of “time interval” points to an interval alongside the time axis, whereas the mathematical definition of S which you refer to as “time interval” actually deals with a space-time interval, i.e. a curved line which does not coincide with the time axis. Your mathematical derivation is perfect, but the english language you display is not in accordance with it. We have had this problem all along this thread: I criticize the language used by physicists and they answer that their maths formalism is perfect. It is perfect indeed, but this is not the point. It is clear we won't agree until this gets sorted out. At least I get the feeling that I finally succeeded to identify the root cause of all these discrepancies. Hopefully there is a margin for progressing toward a common understanding. Thanks a lot for your efforts.
 
  • #87
nitsuj said:
Does the above post mean that clocks measure spacetime, not just time?
I think the last post by stevendaryl was very helpful insofar it becomes clear that a clock delivers an invariant measure of a space-time interval along a one-dimensional curve. Since this curve does not, in general, coincide with the time coordinate axis, I think it is misleading to claim that a clock measures a time interval. I'm the only one defending this, so far.
 
  • #88
Sugdub said:
cannot be eliminated as long as physicists claim that a clock actually measures a time interval.

And it should not, because that is by definition what a clock does. That you in SR chose to define a coordinate ##t## and call it a "time coordinate" is unrelated to this fact and in my opinion more symptomatic of the coordinate actually behaving as the time for an observer following a world line where only this coordinate changes.

Sugdub said:
No. the curved line is not alongside the time axis. So it is not appropriate to call this a "time interval". I've no problem with the maths definition, but I strongly disagree with the naming.
Again you have it backwards, the "fault" here if there is one is not in calling what the clock measures "time", but calling the time axis "time".

Sugdub said:
The semantics of “time interval” points to an interval alongside the time axis

Physicists, in particular the ones fairly familiar with GR will disagree with you. What you call your coordinates is utterly irrelevant to the physics.
 
  • #89
Sugdub said:
I think the last post by stevendaryl was very helpful insofar it becomes clear that a clock delivers an invariant measure of a space-time interval along a one-dimensional curve. Since this curve does not, in general, coincide with the time coordinate axis, I think it is misleading to claim that a clock measures a time interval. I'm the only one defending this, so far.

Well, whether we are talking about Newtonian physics or special relativity or general relativity, there are two different notions of "time". One is a coordinate, which depends on a coordinate system, and the second is a measurable quantity, which only depends on having a clock. When someone says to bake the cookies for 15 minutes, she is talking about time as a measurable quantity. When someone says to meet her at the park at 12:30 am, she is talking about time as a coordinate. Of course, given Newtonian physics, the two are simply related: the measurable quantity, elapsed time, is just the difference between two coordinate times.

In SR and GR, the relationship between the two notions of time becomes more complicated. So people use "proper time" and "coordinate time" to indicate which notion is meant. But they are both rooted in the different notions of time from Newtonian/Galilean physics.
 
  • #90
stevendaryl said:
Of course, given Newtonian physics, the two are simply related: the measurable quantity, elapsed time, is just the difference between two coordinate times.

Actually, even ignoring relativity, the relationship between coordinate time and elapsed time can be a lot more complicated. If I tell you that one event takes place in Paris on June 23, 1987 at 12:45 pm, and a second event takes place in New York on December 3, 2015 at 10:30 am, it's actually pretty complicated to convert those coordinates to an elapsed time. You have to take into account time zones and leap years and conversions between minutes, hours, days and years. But in Newtonian physics, it's possible (though people don't do it) to have a coordinate time that is simply a real number, no matter what your location, and elapsed time is always the difference between two coordinate times.
 
  • #91
Sugdub said:
I mean that I've never seen a statement whereby the measure S of a space-time interval varies depending on the path followed end-to-end, I've never seen a statement whereby what a clock measures is nothing else than S along a definite path. These are things you don't find in presentations of SR easily accessible by non-physicists.

Ah, I see. Yes, pop science or layman's presentations of SR (like pop science or layman's presentations of science in general) don't take the same care as textbooks or scientific papers do. That's why you shouldn't try to learn a science from pop science or layman's presentations. Textbooks on SR, at least the ones I'm familiar with, do address these points.

Sugdub said:
In the Newtonian context, there is no doubt that what a clock measures relates to an interval alongside the time axis.

No, this is not correct. In Newtonian physics, clocks measure absolute time, which is not linked to the "time axis" of any inertial frame. (It can't be, because the "time axes" of different inertial frames are different, but absolute time is the same in all of them.) It appears that your confusion about terminology in SR arises from a confusion about terminology in Newtonian physics.

Sugdub said:
The semantics of “time interval” points to an interval alongside the time axis

No, it doesn't. See above.

As a further point, the semantics of "time interval", or any such term involving "time", has to change when you go from Newtonian physics to SR, because SR does not have absolute time. So your general argument that we should adjust the semantics of terms like "time interval" so they match the Newtonian semantics is not valid, because it can't be done.
 
  • #92
Orodruin said:
And it should not, because that is by definition what a clock does. ... Again you have it backwards, the "fault" here if there is one is not in calling what the clock measures "time", but calling the time axis "time".
Excellent. I'm ready to follow whichever representation system provided it is internally consistent. According to your suggestion, clocks will be said measuring “time” intervals and thus the twins will effectively "age" differently. Clocks will follow geodesic lines in a 4-dimensions manifold, its geometrical structure (curvature) being dependent on the prevailing physical conditions, and this will in turn determine the coordinate axes (curved lines).

However “time dilation” will need re-naming since it won't deal any longer with a “time” interval and the coordinates of today's “space-time” which will no longer be called “space” and “time”. That's fine with me. For what concerns this specific thread, I found today's language being inconsistent because the terms "time dilation" and "proper time" can't both refer to a time interval. Also the path followed by the clock did not coincide with the "time" coordinate axis. Again the maths are correct but the language used by physicists was so far inconsistent.
Should the above be acceptable by physicists, I think it positively resolves my long-lasting discrepancy. Thanks a lot.
 
  • #93
Sugdub said:
Clocks will follow geodesic lines in a 4-dimensions manifold

No. Clocks can follow any timelike worldline. There is no requirement that it be a geodesic. The traveling twin's clock in the twin paradox follows a non-geodesic worldline.

Sugdub said:
geometrical structure (curvature) being dependent on the prevailing physical conditions

Yes, if by "prevailing physical conditions" you mean "the stress-energy tensor".

Sugdub said:
this will in turn determine the coordinate axes

No. Coordinates are an arbitrary choice; there is no requirement that a particular set of coordinate axes must be chosen.

Sugdub said:
“time dilation” will need re-naming since it won't deal any longer with a “time” interval and the coordinates of today's “space-time” which will no longer be called “space” and “time”.

I don't understand how you're getting any of this out of what we've been saying. Your understanding of how the terms "time" and "space" are used is incorrect, and we've been telling you so for many posts now. In the particular passage you quoted, Orodruin was not saying that the "time axis" of a coordinate chart is not a "time" coordinate; he was saying that coordinates are an arbitrary choice, so you should stop fixating on the "time axis" of an arbitrarily chosen coordinate chart, and start thinking about actual observables, like what a clock reads as it follows a particular timelike curve.

Sugdub said:
I found today's language being inconsistent because the terms "time dilation" and "proper time" can't both refer to a time interval.

No, you found it inconsistent because your understanding of it is incorrect.

Sugdub said:
the path followed by the clock did not coincide with the "time" coordinate axis.

So what? Coordinates are an arbitrary choice.

Sugdub said:
the maths are correct but the language used by physicists was so far inconsistent.

No, your understanding of the language is incorrect.

Sugdub said:
Should the above be acceptable by physicists

Not likely since it's based on an incorrect understanding of the issues involved.
 
  • #94
Sugdub said:
... I think it is misleading to claim that a clock measures a time interval. I'm the only one defending this, so far.


In turn do you find it misleading to claim a ruler measures length? In other words do you find your perspective makes sense when seen from the perspective of length?
 
  • #95
Sugdub said:
Where has it been explained that a clock measures amounts of the S quantity, i.e. amounts of “space-time”? I can't remember any presentation of SR, any lecture heading in this direction.
It is in any mainstream SR or GR textbook, it is even in the Wikipedia entry on proper time.

Sugdub said:
For me the wording “proper time” is not only highly misleading, it is symptomatic of a misconception about what gets actually measured: why did physicists introduce this wording whereas “space-time” was already available and fully appropriate?
All proper times are spacetime intervals, but not all spacetime intervals are proper time. Proper time is the spacetime interval along a purely timelike world line. There are spacelike, null, and mixed worldlines also.

Complaining about bad terminology is fruitless. Even widespread disagreement with a term can be insufficient, for example"relativistic mass". If all the top scientists can't get rid of "relativistic mass" then you are not going to be able to get rid of "proper time". Besides, it is a useful term, with a more specific meaning than just spacetime interval.
Sugdub said:
Subtracting S' from S is certainly possible, but this so-called “difference in ageing” can in no way be considered as a difference in the age of the twins.
Of course it can. The human body can be used as a clock. Not a very accurate clock, but a clock nonetheless.
 
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  • #96
Sugdub said:
I referred to “a pair of time-like physical events”. This is certainly not correct: “time-like” relates to the pair, not to individual events. So a better wording would be “a time-like pair of physical events”, with “time-like” indicating that there exists an inertial frame of reference in which the physical events at stake are represented as being co-located. Hopefully this is what you call a “timelike path” and the following statement will be backed-up: “ A clock delivers an invariant measure of the space-time interval along a path connecting a time-like pair of physical events”. Please let me know.
The correct wording is "a pair of timelike separated events", but I understood what you meant to begin with so I didn't make a big deal of it. It is the separation that is timelike, the events are just events. Timelike separated events have a timelike path which connects them, and a timelike path is a path whose tangent vector is timelike at all events along the path.

I would not use the description in terms of inertial frames since there may not be a global inertial frame at all if you are dealing with GR. However, if you are in flat spacetime and if you have a pair of timelike separated events using the general definition, then your definition follows.

Yes, a clock measures the spacetime interval along its worldline, and that is invariant.

Sugdub said:
Let's now come back to my post #53 and consider the “ageing” of the twins along their respective journeys. There is absolutely no doubt that the word “ageing” has been chosen because it designates what we usually consider being an increase in the age of the twins, hence a “time” interval. Now we must acknowledge that “ageing” actually designates an increase in S, an amount of space-time, the measure of a space-time interval.
Yes.

Sugdub said:
Subtracting S' from S is certainly possible, but this so-called “difference in ageing” can in no way be considered as a difference in the age of the twins.
Sure it can. Both S' and S are invariant numbers, true in any frame, they both represent ages, they have the same units and so forth, so subtracting them is a well-defined operation. If I am 40 and my wife is 37 then everyone I know would consider the difference in our age to be 3 years.

Sugdub said:
How could that lead to a statement whereby one of the twins comes back “younger” than the other?
The word "younger" means less age.

Sugdub said:
The only way would be to isolate the “time” components of S and S' respectively and to subtract one from the other
Why would you need to do that. Subtracting the spacetime interval, or proper time is sufficient. No need to take an invariant and break it into components.

Sugdub said:
... but first, one would need to ascertain that it is physically meaningful to breakdown S and S' onto the same base of the same manifold (I've never seen any consideration about this) and second, one would have to ascertain that the difference between both “time” components is frame-invariant (which I believe is not true: only the difference between S and S' is frame-invariant).
I see no benefit it breaking it into components

Sugdub said:
Both twins have a different life history life history. A comparison can certainly be drawn, but no objective qualification of the difference can be made in terms of a frame-invariant time interval. So a statement whereby one of the twins comes back “younger” or “ages less” propagates an erroneous conclusion.
What is erroneous? Seems fully justfied to me

Sugdub said:
However your inputs show that semantic characterisations accounting for a “time” interval are necessarily frame-variant. Therefore I think such expressions should be firmly rejected.
I don't follow either the "semnatic characterisation" or the resulting "firmly rejected"
 
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<h2>1. What is time dilation in Special Relativity?</h2><p>Time dilation is a phenomenon in which time appears to pass slower for an observer who is moving at high speeds relative to another observer. This is a result of the principles of Special Relativity, which state that the laws of physics are the same for all observers in uniform motion.</p><h2>2. Why does time dilation occur in Special Relativity?</h2><p>Time dilation occurs in Special Relativity because of the relationship between space and time. According to Einstein's theory, the faster an object moves through space, the slower it experiences time. This means that as an object approaches the speed of light, time appears to slow down for that object.</p><h2>3. How does Special Relativity cause time dilation?</h2><p>Special Relativity causes time dilation through the concept of relative motion. When two observers are moving at different speeds relative to each other, they will experience time differently. This is because the speed of light is constant for all observers, regardless of their relative motion.</p><h2>4. Can time dilation be observed in everyday life?</h2><p>Yes, time dilation can be observed in everyday life, although the effects are very small at typical speeds. For example, GPS satellites have to take into account the effects of time dilation due to their high speeds in orbit around the Earth in order to accurately function.</p><h2>5. How does time dilation impact our understanding of time?</h2><p>Time dilation challenges our traditional understanding of time as a constant and absolute quantity. It suggests that time is a relative concept and can be experienced differently depending on the observer's frame of reference. This has profound implications for our understanding of the universe and the nature of reality.</p>

1. What is time dilation in Special Relativity?

Time dilation is a phenomenon in which time appears to pass slower for an observer who is moving at high speeds relative to another observer. This is a result of the principles of Special Relativity, which state that the laws of physics are the same for all observers in uniform motion.

2. Why does time dilation occur in Special Relativity?

Time dilation occurs in Special Relativity because of the relationship between space and time. According to Einstein's theory, the faster an object moves through space, the slower it experiences time. This means that as an object approaches the speed of light, time appears to slow down for that object.

3. How does Special Relativity cause time dilation?

Special Relativity causes time dilation through the concept of relative motion. When two observers are moving at different speeds relative to each other, they will experience time differently. This is because the speed of light is constant for all observers, regardless of their relative motion.

4. Can time dilation be observed in everyday life?

Yes, time dilation can be observed in everyday life, although the effects are very small at typical speeds. For example, GPS satellites have to take into account the effects of time dilation due to their high speeds in orbit around the Earth in order to accurately function.

5. How does time dilation impact our understanding of time?

Time dilation challenges our traditional understanding of time as a constant and absolute quantity. It suggests that time is a relative concept and can be experienced differently depending on the observer's frame of reference. This has profound implications for our understanding of the universe and the nature of reality.

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