Twin Paradox: Pensioner's Perspective on Length Contraction

  • Thread starter fxfocus
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In summary: Length contraction is irrelevant to the twin "paradox". All that matters is that you realize that they have taken different world lines and one of those world lines has more clock ticks than the other.In summary, the twins experience different ages depending on which frame of reference they are in.
  • #1
fxfocus
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Hi, I'm a pensioner with little formal education, still struggling with SR and with no knowledge at all of GR.

When people ask why the twins age differently in a situation which appears symmetrical depending on which frame of reference you use; I see answers along the lines of...

Only the traveling twin experiences a change of reference or acceleration.

Which I accept, but...

What I haven't seen is any reference to the fact that from either perspective, only the traveling twin experiences length contraction, which shortens the length and thus duration of the journey?

Have I got that wrong?
 
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  • #3
fxfocus said:
Hi, I'm a pensioner with little formal education, still struggling with SR and with no knowledge at all of GR.

When people ask why the twins age differently in a situation which appears symmetrical depending on which frame of reference you use; I see answers along the lines of...

Only the traveling twin experiences a change of reference or acceleration.

Which I accept, but...

What I haven't seen is any reference to the fact that from either perspective, only the traveling twin experiences length contraction, which shortens the length and thus duration of the journey?

Have I got that wrong?
Length contraction is irrelevant to the twin "paradox". All that matters is that you realize that they have taken different world lines and one of those world lines has more clock ticks than the other.
 
  • #4
Nobody experiences length contraction or time dilation. It is, genuinely, something that always happens to other people. So, from the stay-at-home's frame, the rocket is contracted and time-dilated but neither the planets nor the space between them are contracted. Meanwhile, from the traveller's frame, the rocket is not contracted but the planets and the space between them are.

It turns out that the elapsed time on a path through spacetime is equal to a quantity called the "interval", which is closely analogous to the length of the path. The reason the twins are different ages is that they followed paths of different "lengths". At least one path must include a bend (acceleration) if the two are to meet again, which is where the "acceleration causes the difference" story comes from. It works in this example, but the path length explanation is more general.
 
  • #5
Ibix said:
Nobody experiences length contraction or time dilation. It is, genuinely, something that always happens to other people. So, from the stay-at-home's frame, the rocket is contracted and time-dilated but neither the planets nor the space between them are contracted. Meanwhile, from the traveller's frame, the rocket is not contracted but the planets and the space between them are.

It turns out that the elapsed time on a path through spacetime is equal to a quantity called the "interval", which is closely analogous to the length of the path. The reason the twins are different ages is that they followed paths of different "lengths". At least one path must include a bend (acceleration) if the two are to meet again, which is where the "acceleration causes the difference" story comes from. It works in this example, but the path length explanation is more general.

It's really the length of the path I'm trying to get at. It seems to me that the traveling twin takes the shorter path due (at least in part) to length contraction. Let's say we place a pebble at the turn around point. This pebble would always be at rest with respect to the stay at home twin but whether the traveling twin moves to the pebble or the pebble moves to the traveling twin only the traveling twin would perceive the journey to be shorter.

Fully expecting and happy to be told I'm wrong but just can't yet see why?
 
  • #6
That is the traveller's explanation for why her clocks show less elapsed time than a Newtonian prediction. That isn't the paradox, however. The paradox is that, in the traveller's frame(s), the Earth is moving so its clocks tick slower, so surely the Earthbound twin should be younger when they meet up.

One resolution to this is to note that when the traveller changes direction she changes her definition of "now, on Earth" in a way that accounts for the error. The other is to use the interval argument I made in my last post.
 
  • #7
fxfocus said:
Hi, I'm a pensioner with little formal education, still struggling with SR and with no knowledge at all of GR.

When people ask why the twins age differently in a situation which appears symmetrical depending on which frame of reference you use; I see answers along the lines of...

Only the traveling twin experiences a change of reference or acceleration.

Which I accept, but...

What I haven't seen is any reference to the fact that from either perspective, only the traveling twin experiences length contraction, which shortens the length and thus duration of the journey?

Have I got that wrong?

Yes and no.

You're wrong if you think that the situation is symmetrical. Without using GR, we need two inertial frames of reference to describe the traveling twin, not one. Two and one are not "symmetrical".

You're mostly right when you point out that length contraction and time dilation combine to give a consistent picture where they don't make a consistent picture alone. You're mostly right instead of "spot on" because there's a third effect that you haven't taken into account yet, the relativity of simultaneity.

The notion of proper distance and proper time would be helpful in your understanding. The proper distance between two points is equal to the distance between two points in a frame of reference where they are both not moving. The distance between the two points in either of the two moving frames for the traveling twin is length contracted when compared to the proper distance. "Proper time", which can be throught of as "wristwatch time" is time that is measured along a worldline by a single clock - it's one of the most basic notions of time, as it does not require any notion of a way to "synchoronize" clocks. It does require you to specify the path of the particular clock that measures it.

In terms of proper time, the point is that the sum of the proper times of the traveller heading out and heading back in (this time is the sum of two proper times in two different inertial frames) is lower than the proper time of the traveller who stays put.

Good luck - I'm afraid that you'll find that re-opening this discusion yields the usual results - there isn't that much advantage to opening a new discussion when there's zillions of old ones, the same thing tends to keep happening.
 
  • #8
Apologies to all. I should have made it clearer my objective was not to resurrect a discussion of the twin paradox but to simply verify whether or not the stay at home twin would measure a longer distance to the turnaround point than would the traveling twin when viewed from either perspective. By which I mean whichever frame of reference you consider to be moving. I'm assuming if we marked the turn around point with a pebble then this pebble would always be at rest with respect to the stay at home twin.

The reason for asking is that I was under the impression for a long time that the twins scenario was symmetrical (excluding turn around) but now I'm thinking the pebble (or turn around point) breaks the symmetry because it can be considered attached to the stay at home twin.

Hope this helps, if not I promise not to labour the point further ;o)

Edit: I should have said that for this purpose I'm not taking into account any acceleration associated with the turn around.
 
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  • #9
fxfocus said:
I'm assuming if we marked the turn around point with a pebble then this pebble would always be at rest with respect to the stay at home twin.

If you assume this, then yes, the distance from the stay-at-home twin to the turnaround point will be larger in the stay-at-home twin's frame than it will be in the traveling twin's frame. But that asymmetry is because you made an asymmetric assumption: you assumed that the turnaround point is at rest relative to the stay-at-home twin.

Suppose, instead, that we assume that the traveling twin himself marks the "turnaround point" by firing his rockets, and that the way we will measure the distance from the turnaround point to the stay-at-home twin is to use a pebble that is moving at the same velocity, relative to the stay-at-home twin, as the traveling twin on his outbound leg, and which is just passing the stay-at-home twin at the instant, in the traveling twin's frame on his outbound leg, that the traveling twin reaches the turnaround point. The distance between this pebble and the traveling twin, in the traveling twin's frame, will be larger than the distance between them in the stay-at-home twin's frame (which he can measure by simply measuring the time from when the traveling twin leaves to when the pebble passes him, and multiplying by the known speed of the two relative to him); so in this frame, it is the stay-at-home twin whose distance to the turnaround point is "length contracted".

The key point to take away from all this is that length contraction, time dilation, and relativity of simultaneity are all frame-dependent, so you have to be careful trying to reason about them, because you can make them appear to change by just changing which frame you pick. But changing which frame you pick can't change any of the actual physics. The actual physics is contained in invariants--things that don't change when you change frames. For example, the fact that, when the traveling twin returns, he has aged less than the stay-at-home twin, is an invariant. But things like the "distance to the turnaround point" are not.
 
  • #10
PeterDonis said:
If you assume this, then yes, the distance from the stay-at-home twin to the turnaround point will be larger in the stay-at-home twin's frame than it will be in the traveling twin's frame. But that asymmetry is because you made an asymmetric assumption: you assumed that the turnaround point is at rest relative to the stay-at-home twin.

Thanks for that. I think it was when I first realized the turnaround point was at rest relative to the stay at home twin that the penny dropped for me. I understand you might construct scenarios where that isn't the case but I had not considered those. Many scenarios have the traveling twin visiting a distant planet before returning and perhaps that's the example I should have used.

So If I read your answer right, then just the length contraction alone would result in the traveling twin being younger even if we discounted the acceleration effects?

I think the most important thing I have learned from this discussion is to spend some time carefully phrasing my questions in future. ;o)
 
  • #11
fxfocus said:
just the length contraction alone would result in the traveling twin being younger even if we discounted the acceleration effects?

No. Length contraction is best understood as an effect, not a cause. (The same is true for time dilation and relativity of simultaneity.) The cause of the traveling twin being younger when he returns is that he has followed a different path through spacetime, one which has a shorter elapsed time than that of the stay-at-home twin. In other words, it's the geometry of spacetime. Length contraction, time dilation, and relativity of simultaneity are just particular manifestations of the geometry of spacetime; in themselves they don't cause anything.
 
  • #12
PeterDonis said:
No. Length contraction is best understood as an effect, not a cause. (The same is true for time dilation and relativity of simultaneity.) The cause of the traveling twin being younger when he returns is that he has followed a different path through spacetime, one which has a shorter elapsed time than that of the stay-at-home twin. In other words, it's the geometry of spacetime. Length contraction, time dilation, and relativity of simultaneity are just particular manifestations of the geometry of spacetime; in themselves they don't cause anything.

Thanks for that. Seems I just keep asking the wrong questions so I'll stop now.

I am left with the impression that excluding the acceleration effects the traveling twin will still be younger in the scenario where the pebble is fixed.

Thanks to all who contributed to this thread.
 
  • #13
Marvellous isn't it..!

Within minutes of my last post I came across a post on another forum which I think elucidates my thinking much better than my clumsy attempts here.

I'm not sure if I'm allowed to place links to other forums so I'll take the liberty of quoting the post...

... because there is no length contraction for the distance between two reference frames. The length (or distance) must be found in one reference frame, and the observer must be in another reference frame, he may not be part of the reference frame of the distance.

By consequence, it is not the distance between muon and Earth which is contracted. It is the distance between the starting point A of the muon and Earth (if we suppose that the muon is traveling from A to Earth).

From the Earth frame the distance A-Earth is at its largest. For the muon frame, the distance A-Earth is contracting according to its relative velocity.

Edit: Which I think pretty much ties in with my original post :eek:)
 
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  • #14
In addition to the pebble you've got at the turn-around point, imagine a stone tethered to the rocket and trailing behind it.

Earth frame: Pebble-Earth distance is fixed and equal to ##L##.

Rocket frame: Stone-rocket distance is fixed and equal to ##L##.

People in the Earth frame will observe the stone-rocket distance contracted. People in the rocket frame will observe the pebble-Earth distance contracted.
 
  • #15
Mister T said:
In addition to the pebble you've got at the turn-around point, imagine a stone tethered to the rocket and trailing behind it.

Earth frame: Pebble-Earth distance is fixed and equal to ##L##.

Rocket frame: Stone-rocket distance is fixed and equal to ##L##.

People in the Earth frame will observe the stone-rocket distance contracted. People in the rocket frame will observe the pebble-Earth distance contracted.

I don't see the rocket at rest with respect to the stone. From either perspective the rocket must move between Earth and the stone, otherwise (I think) you are comparing apples with oranges.

Edit: Woops..! I misread your post and confused the stone with the pebble. Your absolutely right of course.
 
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FAQ: Twin Paradox: Pensioner's Perspective on Length Contraction

What is the Twin Paradox?

The Twin Paradox, also known as the Twin Paradox of Relativity, is a thought experiment in physics that explores the concept of time dilation and the effects of traveling at high speeds on time. It involves two identical twins, where one stays on Earth and the other travels at near-light speeds, and upon their reunion, the traveling twin would have aged slower than the twin on Earth.

How does the Twin Paradox relate to the concept of length contraction?

The Twin Paradox highlights the concept of length contraction, which is a consequence of the theory of relativity. Length contraction refers to the shortening of an object's length in the direction of its motion when it is moving at high speeds. In the Twin Paradox, the traveling twin experiences length contraction, as their journey at near-light speeds causes their length to appear shorter to the stationary twin on Earth.

Can the Twin Paradox be observed in real life?

The Twin Paradox is a thought experiment and cannot be directly observed in real life. However, the effects of time dilation and length contraction have been observed and confirmed through experiments with particles accelerated to near-light speeds in particle accelerators.

How does the Twin Paradox affect the aging of the twins?

According to the theory of relativity, the traveling twin in the Twin Paradox would experience time dilation, where time would pass slower for them compared to the twin on Earth. As a result, the traveling twin would age slower and upon their reunion, they would be younger than the twin on Earth.

Is the Twin Paradox a paradox or a real phenomenon?

The Twin Paradox is often referred to as a paradox because it seems to contradict common sense and logical reasoning. However, it is a real phenomenon that can be explained by the theory of relativity. The apparent paradox is resolved by taking into account the relative motion and frame of reference of the twins.

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