Understand Special Relativity and Time paradox

In summary, the first principle of special relativity states that the laws of physics are the same for any inertial referential. In the case of two twins, one staying on Earth and the other traveling in a spaceship with velocity 0.5c, time will pass more slowly for the traveling twin according to the principle of moving referentials. However, the Physics laws remain the same for both twins. When the traveling twin returns, he will have aged less compared to the twin who stayed on Earth, due to the symmetry of the event and the fact that acceleration is relative. This is known as the twin paradox.
  • #141
DaleSpam said:
Well, "invariant" is well-defined, but I don't think "physical fact" is well defined. However I would tend to agree that under a reasonable definition of "physical fact" that frame invariant facts are more likely to qualify than frame variant ones.
If we take "invariant" as basic term it does not have to be well defined. In fact basic terms can't be well defined.

It's like with axiomatic systems and primitive notions (undefined terms).
 
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  • #142
DaleSpam said:
I would tend to agree that under a reasonable definition of "physical fact" that frame invariant facts are more likely to qualify than frame variant ones.

Actually, now that we seem to be clearing up confusion, I feel the need to insert some more. :wink:

The sorts of things we have been calling "frame-invariant" actually can include a lot of things that could also be called "frame-variant". For example, consider the energy of an object. It varies from frame to frame; but given any frame, I can easily construct an invariant that expresses the energy of the object as measured in that frame. I just pick an observer at rest in the frame whose worldline crosses that of the object at a chosen event, and take the inner product of the observer's 4-velocity at that event with the object's 4-momentum at that same event:

[tex]E = \eta_{\mu \nu} u^{\mu} p^{\nu}[/tex]

The number E is usually thought of as the "time component" of the object's 4-momentum in the given frame, and hence as a "frame-variant" quantity; but as I've written it above, it should be obvious that E is an invariant; it's the inner product of two 4-vectors, and inner products are preserved by Lorentz transformations.

If I look at this inner product in a different frame, [itex]p^{\nu}[/itex] will have different components, but so will [itex]u^{\mu}[/itex], because I defined [itex]u^{\mu}[/itex] as the 4-velocity of a particular observer in a particular state of motion. That observer won't be at rest in the new frame, so [itex]u^{\mu}[/itex] in the new frame will have spatial components as well as a time component; and that will compensate for the change in the components of [itex]p^{\nu}[/itex] in just the right way to keep the inner product E constant.

The point of all this is that focusing attention on "invariants" does not cost us anything. We can still talk about all the quantities that we would normally think of as "frame-variant", like components of vectors; we just have to define them properly. When we do, we see that they represent perfectly good "physical facts". The number E is not just the "time component" of [itex]p^{\nu}[/itex] in a particular frame; it represents the physical fact that a particular observer, in a particular state of motion, measures a particular object to have a particular energy.
 
  • #143
zonde said:
I want to oppose statements like this statement of DaleSpam (suggesting that invariants somehow make physics law more "real" than coordinate dependant quantities). But I wanted to understand what is the motivation behind statements like that.
I dislike the word "real" so I wouldn't say that they are more "real" written in a coordinate independent fashion. I would say that they are more accurate, which is true since it avoids the approximation I mentioned above. I could also say that they are more general, which should be obvious I hope.
 
  • #144
PeterDonis said:
The number E is not just the "time component" of [itex]p^{\nu}[/itex] in a particular frame; it represents the physical fact that a particular observer, in a particular state of motion, measures a particular object to have a particular energy.
It sounds like you are drawing the distinction between the purely mathematical notion of a "coordinate system" and the purely physical notion of a "frame of reference." It's true that once we choose a convention for creating coordinates, then there is a one-to-one mapping between the two notions, but since we don't have to agree on any such convention, how things depend on coordinates is more general, and less physically important, than how they depend on reference frames (states of the observers).

We should probably dispense with redundancies right away by picking a particular coordinate convention (like Einstein simultaneity in the absence of gravity, or comoving-frame coordinates in cosmology), and noting that the rules of tensors automatically (and trivially) navigate for us the redundancies of other coordinate conventions. There's no physics in that yet, it's just the mathematical requirement that when we tell our stories using coordinates, we will need the mathematical forms of tensors to keep the stories the same, even when all the observers are in the same state. The physics appears when we ask how different states of the observers will affect their observable outcomes, which is where every particular type of relativity (i.e., the appropriate metric in the contractions) distinguishes itself. Indeed I would argue that Einstein's relativity should not be called the theory of relativity, nor the theory of invariants, because neither term distinguishes it from every other set of relativistic invariants. We should call it Einsteinian relativity, or the theory of Einstein invariants.
 
  • #145
Ken G said:
It sounds like you are drawing the distinction between the purely mathematical notion of a "coordinate system" and the purely physical notion of a "frame of reference."

Yes, that's one way of looking at it. The 4-velocity [itex]u^{\mu}[/itex] is the timelike vector of the observer's frame. As such, it's a coordinate-free geometric object; sometimes it's convenient to describe it in a particular coordinate chart, but we can reason about it without doing that.
 
  • #146
PeterDonis said:
For example, consider the energy of an object. It varies from frame to frame; but given any frame, I can easily construct an invariant that expresses the energy of the object as measured in that frame. I just pick an observer at rest in the frame whose worldline crosses that of the object at a chosen event, and take the inner product of the observer's 4-velocity at that event with the object's 4-momentum at that same event:

[tex]E = \eta_{\mu \nu} u^{\mu} p^{\nu}[/tex]
This should be expected. When anyone performs a measurement the outcome of that measurement is frame invariant. Otherwise different frames would predict that the same experiment would generate different numbers. So there must be some mechanism for converting frame variant components into frame invariant scalars.

However, I think that it is important to note that the invariant quantity you labeled E is NOT the energy, except in the rest frame of the observer. So "energy" is frame variant, but a particular measurement of energy produces an invariant number. Other frames will disagree that the number produced by that measurement represents the energy.

I wish I knew a better way to state that.

PeterDonis said:
The point of all this is that focusing attention on "invariants" does not cost us anything. We can still talk about all the quantities that we would normally think of as "frame-variant", like components of vectors; we just have to define them properly. When we do, we see that they represent perfectly good "physical facts". The number E is not just the "time component" of [itex]p^{\nu}[/itex] in a particular frame; it represents the physical fact that a particular observer, in a particular state of motion, measures a particular object to have a particular energy.
Well said. But again, the number E is not the energy except in one frame.
 
  • #147
DaleSpam said:
I wish I knew a better way to state that.

I wish I did too. You're quite right, the way I stated it is open to misinterpretation, but so is every other way I can think of.
 
  • #148
DaleSpam said:
I wish I knew a better way to state that.
It was pretty clear to me. :)
 
  • #149
Ken G said:
hence the "Andromeda paradox" of this thread

What is the "Andromeda paradox"?
 
  • #151
Skipping the notion of velocity 0.5c (or half-light speed), in physics, the twin paradox is a fun thought experiment in special relativity involving identical twins, one of which makes a journey into space in a high-speed rocket and returns home to find that the twin who remained on Earth has aged more.

So while I have given the answer as provided on the internet, how does one arrive at this conclusion? The time differential is based on naive application of time dilation wherein the rate of time is influenced by the rate of gravitational acceleration. Time dilation postulates that the faster an object is moving, whether gravitationally accelerated or thrust propelled, then the slower time progresses for that object in relation to a more stationary observer. The proof for this concept has been demonstrated via twin atomic clocks appositely positioned, one off Earth in outer Space and another remaining on Earth.

And yet time dilation has more to do with impractical interpretations rather than applied science. This result appears puzzling because each twin sees the other twin as traveling, and so, according to a naive interpretation of time dilation, each should paradoxically find the other to have aged more slowly. However, this scenario can be resolved within the standard framework of special relativity because the twins are not within equal frames of reference; the space twin’s rate of time was gravitationally influenced by its acceleration. The naïve expectation is, of course, that the space traveling twin would maintain his time differential (younger self) once he joined his brother on Earth.

However this is not the conclusion of the analysis. Another experiment based its results on twin clocks placed on aircraft flying in opposing directions parallel with the spin of the Earth. The logic being the experiment was that gravitational acceleration follows the spin of the Earth. According to special relativity, the rate of a clock is greatest according to an observer who is at rest with respect to the clock. In a frame of reference in which the clock is not at rest, the clock runs more slowly. Considering this experiment in a frame of reference at rest with respect to the center of the Earth gravitational field, a clock aboard the plane moving eastward, in the direction of the Earth's gravitational rotation, had a greater velocity (resulting in a relative time loss) than one that remained on the ground, while a clock aboard the plane moving westward, against the Earth's gravitational rotation, had a lower velocity than one on the ground (resulting in a relative time gain). For some scientists, this was enough to expect that the space traveling twin would have to endure a like opposing gravitational resistance on his return to his brother’s Earth-bound inertial frame of reference. Ergo, both brothers would be the same age.
 
  • #152
SJBauer said:
So while I have given the answer as provided on the internet, how does one arrive at this conclusion?

The general principle that covers all of these kinds of cases is that the proper time experienced between two events depends on the path taken--i.e., different worldlines can have different lengths. That resolves the standard "twin paradox" as well as variants like the Hafele-Keating experiment (atomic clocks being flown around the world) and GPS (the natural "rate of time flow" aboard the GPS satellites is different than on the ground).

SJBauer said:
This result appears puzzling because each twin sees the other twin as traveling, and so, according to a naive interpretation of time dilation, each should paradoxically find the other to have aged more slowly. However, this scenario can be resolved within the standard framework of special relativity because the twins are not within equal frames of reference

This doesn't matter; you can do the entire analysis in a single frame, using the general principle I gave above. See, for example, here:

http://math.ucr.edu/home/baez/physics/Relativity/SR/TwinParadox/twin_spacetime.html

SJBauer said:
The naïve expectation is, of course, that the space traveling twin would maintain his time differential (younger self) once he joined his brother on Earth.

This is also the correct answer, derived using the analysis as above.

SJBauer said:
Another experiment based its results on twin clocks placed on aircraft flying in opposing directions parallel with the spin of the Earth. The logic being the experiment was that gravitational acceleration follows the spin of the Earth.

You're talking, I assume, about the Hafele-Keating experiment:

http://en.wikipedia.org/wiki/Hafele–Keating_experiment

I'm not sure what you mean by "gravitational acceleration follows the spin of the Earth". The point of the experiment was that there are *two* effects involved: what the Wikipedia calls "kinematic time dilation", due to relative motion, and gravitational time dilation, due to altitude. The experiment tested the prediction resulting from combining these two effects; and the prediction was confirmed.

SJBauer said:
Considering this experiment in a frame of reference at rest with respect to the center of the Earth gravitational field, a clock aboard the plane moving eastward, in the direction of the Earth's gravitational rotation, had a greater velocity (resulting in a relative time loss) than one that remained on the ground, while a clock aboard the plane moving westward, against the Earth's gravitational rotation, had a lower velocity than one on the ground (resulting in a relative time gain).

Yes, but both aircraft were also at a higher altitude than the ground clock, which resulted in a gravitational time gain for both. For the eastward moving clock, the kinematic time loss was greater than the gravitational time gain, for a net time loss; for the westward moving clock, both the kinematic and the gravitational effects gave a time gain. But to get the right answer as shown by the experiment, you have to take *both* effects into account. Just the kinematic effect alone does not give the correct answer.

SJBauer said:
For some scientists, this was enough to expect that the space traveling twin would have to endure a like opposing gravitational resistance on his return to his brother’s Earth-bound inertial frame of reference. Ergo, both brothers would be the same age.

This is not correct. Why do you think this would happen?
 
  • #153
Alain2.7183 said:
What is the "Andromeda paradox"?

I’ll try to illustrate the Andromeda Paradox with the illustration below (patterned after Roger Penrose’s book “The Emperor’s New Mind”).

Ruth and Bill walk past each other on the sidewalk. They move at the same speed in opposite directions with respect to the rest frame of the earth. Thus, each of them occupies a different simultaneous space (they are associated with two different inertial frames). Now, consider the worldline of the distant Andromeda galaxy (we will assume the Andromeda Galaxy is at rest in the rest frame of the earth). There is a point on the Andromeda worldline that is in the simultaneous space of Bill as Bill and Ruth pass each other on the street. But, as they pass, there is a different point on the Andromeda worldline that is in the simultaneous space of Ruth (a point later in Andromeda time for Ruth than for Bill).

In Bill’s simultaneous space a committee in the Andromeda Galaxy is meeting to decide whether to attack Earth. However, in Ruth’s simultaneous space, the decision has already been made and the attack fleet has already been launched.

AndromedaParadox_bob2.jpg
 
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  • #154
DaleSpam said:
This should be expected. When anyone performs a measurement the outcome of that measurement is frame invariant. Otherwise different frames would predict that the same experiment would generate different numbers. So there must be some mechanism for converting frame variant components into frame invariant scalars.
Yes, I was thinking about the same.
So what could be this mechanism? One simple way would be that frame variant represents a group of frame invariants. So the mechanism is just picking one certain invariant out of the group.

DaleSpam said:
However, I think that it is important to note that the invariant quantity you labeled E is NOT the energy, except in the rest frame of the observer. So "energy" is frame variant, but a particular measurement of energy produces an invariant number. Other frames will disagree that the number produced by that measurement represents the energy.
But we can draw parallels with mass. And we do speak about rest mass that is mass in one particular frame.
 
  • #155
PeterDonis - Per your question of why I would believe it would be possible for the twins to be of the same age when put back into the same frame of inertial reference. The concept of acceleration toward the speed of light puts the space traveling twin in a differing frame of reference. In order to be rejoined with his brother, he must decelerate from the speed of light. The process of acceleration causes a time dilation: i.e. whenever energy is added to a system, the system gains mass; whenever a system gains mass it further increases time dilation. On the other hand, the process of deceleration requires a resistance to acceleration momentum (kind of like putting on the brakes for the entire time of returning to the Earth-bound brothers frame of reference). The process of deceleration reverses time dilation:i.e. whenever energy is deleted from a system, the system loses mass; whenever a system loses mass it further decreases time dilation. As inducing decelerating momentum requires a stronger opposing force, it actually takes longer to decelerate back to the Earth-bound brother's frame of reference. This lag time accounts for the conservation of time that equalizes the space traveling twins age with that of his Earth-bound brother.
 
  • #156
zonde said:
But we can draw parallels with mass. And we do speak about rest mass that is mass in one particular frame.
I prefer the term "invariant mass" over "rest mass" since a system may not be at rest in any inertial frame, but still has a well defined invariant quantity with units of mass. But your point is well taken. Similarly with proper time and proper length.
 
  • #157
SJBauer said:
The process of acceleration causes a time dilation: ... The process of deceleration reverses time dilation:
These are both incorrect.
 
  • #158
Thinker007 said:
It was pretty clear to me. :)
Thanks! It felt awkward when I wrote it, but maybe it isn't as bad as it seemed.
 
  • #159
bobc2 said:
In Bill’s simultaneous space a committee in the Andromeda Galaxy is meeting to decide whether to attack Earth. However, in Ruth’s simultaneous space, the decision has already been made and the attack fleet has already been launched.

Thanks for that description.

I see how the two different walkers can have different ideas of "now" at Andromeda. But I don't yet understand how you get from there to the "block universe" conclusion.
 
  • #160
Alain2.7183 said:
Thanks for that description.

I see how the two different walkers can have different ideas of "now" at Andromeda. But I don't yet understand how you get from there to the "block universe" conclusion.

This is implied as soon as you acknowledge a couple of observations. First, Ruth and Bill exist together in the black rest frame as well as each of their respective rest frames at the event represented by the passing on the sidewalk. But, the only way that the event of the Andromeda committee meeting and the event of the space fleet launch can both exist is if all events are all there "at once."

That is, if the entire universe exists "all at once" as a 4-dimensional static structure ("block universe"), then there is no problem for two different observers (or any number of observers) to all exist in different cross-sections of the 4-dimensional universe "all at once."

The "all at once" phrase is used by Paul Davies in his book "About Time" when he describes the block universe. Some have trouble with that phrase because it is time related phrase. The question is raised, "To what kind of time does 'all at once' refer?" Is there some hypertime that flows as the static universe just sits there frozen? But, then the discussion seems to get too philosophical for a forum such as ours.

You should understand that most forum members here would insist that the Andromeda Paradox does not represent anything about physical reality. It could be taken as a pedagogical illustration to help graphically visualize aspects of the mathematics of special relativity. They consider that there are other equally valid interpretations of special relativity, such as the Lorentz Aether theory, that are in conflict with any notion that the Andromeda Paradox illustrates something about reality--thus, in that view, the block universe is not to be taken as a true characterization of external physical reality.

One of our members, Vandam, was very passionate about the true physical reality expressed in the block universe interpretation of special relativity. Someone posted a note to me the other day that Vandam has been banned from our forum. Evidently his continual dogmatic insistence about the reality of block universe was considered objectionable (and perhaps that along with some of the strong language used in exchanges with others who strongly disagreed with him--and in fairness to Vandam there was strong language directed at him as well). And as a note to Vandam, in case he still looks in on the forum: Sorry to see you go, colleague. We will miss your perspective on things.

I am not inclined to have any more to say about the block universe, except when feeling obligated to respond to direct questions.

[edit] By the way, some physicists get annoyed by Penrose ignoring the obvious changes to the picture if you were to take into account the tangential velocity of the Earth at the point of Bill and Ruth passing. Then, the orbiting of planets in the respective solar systems. And the relative motion between the Andromeda Galaxy and our Milky Way Galaxy along with the orbiting of our solar system as part of our rotating Galaxy, and the orbiting of the Andromeda solar system along with its rotating Galaxy where that meeting and launch takes place, etc., etc. Penrose would probably reply that it's not worth the distraction of taking all of those things into account since after all is done you would still have the basic Andromeda Paradox effect.
 
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  • #161
bobc2 said:
...I've prepared a set of sketches to help anyone interested visualize what is going on in the 4-dimensional universe with the twins in the context of simultaneity...

Twin_Paradox_D4.png
In an attempt to try to understand your sketches, I have redrawn my diagrams from post #23. I interchanged the colors of the twins to match what you drew and I eliminated the signals going between them for the same reason. In my diagrams, I mark yearly increments of Proper Time for both twins with dots so it was no problem adding in the black circles like you have in your Sketch I. Since simultaneity is marked by the Coordinate Time grid lines (or any other horizontal line), it was no problem adding the horizontal black lines and the blue circles placed on the traveling twin's world line. Here's what I've got so far:

attachment.php?attachmentid=54863&stc=1&d=1358633560.png


But to add in the diagonal blue lines was not trivial because they are not coincident with the blue dots marking yearly increments of Proper Time for the traveling twin. Neither are they coincident with the blue circles. So what I did was transform from the IRF in which the black inertial twin is at rest to the IRF in which the blue traveling twin is at rest during the outbound portion of his trip. Then I added in horizontal blue lines going from the yearly increments of Proper Time for the black inertial twin and going over to the blue traveling twin's world line. These horizontal lines are simultaneous in this IRF. Here's that diagram:

attachment.php?attachmentid=54864&stc=1&d=1358633560.png


Now, I look at the intersections of the horizontal blue lines in relation to the blue dots which enables me to know where to draw the blue diagonal lines on the first diagram. Here's the final diagram:

attachment.php?attachmentid=54865&stc=1&d=1358633560.png


Now this leaves me with a question: what is the purpose of the blue circles?

[NOTE: I want to take this opportunity to point out an error I made in my first post (#7) of this thread. I incorrectly attempted to simplify the formula at the end of the post.]
 

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  • #162
bobc2 said:
That is a philosophically based idea. Einstein cautioned against these kinds of ideas which trap you into solipsism.

You are saying that there is no reality to be associated with the hyperplanes of simultaneity for a given Lorentz frame. I don't think our monitor will want us to continue a discussion along those lines. .


Solipsism seems to be a recurring topic with you. I find this strange because no commentary from anyone in this forum has indicated to me any kind of solipsist bias whatsoever.
as I understand you you think that we can infer a picture of reality that goes beyond direct measurement and instantaneous information. I certainly agree on this point.
SO you ,based on the concept of absolutely invariant light propogation , have infered an instantaeous picture of an extended slice of the world.
Given points A and B an isotropic light burst at the midpiont M would arrive simultaneously at both A and B . Conversely signals from A and B received simultaneously at M would have been emitted simultaneously at A and B.
So then a system of clocks symnchronized on this basis would universally have simultaneously identical proper time readings. This is certainly logical as far as it goes and is of course simply the Einstein synchronization convention in action.
but your interpretation is totally dependent on the isotropic equality of light paths.
I.e., the distance from A to M is not only spatially equal to the distance from B to M but the light paths themselves must be actually equal. A-->M=B-->M
Assuming that this is the case , if we accelerate the system along the A-B vector to a new inertial velocity it is quite obvious that it is not possible that the paths could still be equal.
If the paths are unequal and light is absolutely invariant in speed then, equally obviously, the time between . A-->M could not equal the time bewteen B-->M. So the concept of actual simultaneity based on this premise could not be consistent with reality.

So it appears that you reject the reality infered by logic and physical conception of space and motion as we know it and replace it with a picture dependent on conventional clock readings which is a matter of practicallity and convention, based on an assumption of equal path lengths which we know is not actually true.
Do you have some kind of physical model where ALL light paths between equal distances in ALL frames could be isotropically equivalent?
Do you agree that the assumption of actual simultaneity based on equal light paths and the recognition that such paths cannot be equal in a system in motion are mutally exclusive?
You repeatedly assert that anyone who does not accept your interpretation of actual physical simultaneity of an instant defined by equal system clock readings,- is denying the actuality of a real 3-d slice of spacetime. But this is a gross misrepresentation. I for one have no problem whatsoever accepting such a slice. I assume that the physical structure and interrelationships within an inertial frame would insure some kind of fundamental simultaneity of existence or temporal connection. But this kind of "actual" simultaneity would not necessarily correspond with clocks haviong equivalent proper times which is what you are insisting without justification.
I can't speak for others but I would imagine that the majority simply feel that the surfaces of simultaneity do not represent such a slice of actual simultaneity not that such a slice does not exist.

So I wouldn't say you were a solopsist but you do seem to deny logical inferences regarding reality in favor of a metaphysical (non-logical) worldview.
 
  • #163
bobc2 said:
Twin_Paradox_D4.png


In the sketch below, I've added in a Red guy here in order to make a point about the interesting sequence of simultaneous worlds for the traveling twin as he does his turna-round. So, this additional red guy is at rest along with the black guy. As the Blue guy does his turn-around, the sequence of Black clock readings (as presented in the sequence of Blue's 3-D world cross-sections of the 4-D universe) progress into the future whereas the Red clock readings proceed into the past. As Blue enters the turn-around, the Black clock begins with event "black E" and at the end of the turn-around the last Black clock reading corresponds to event "black h." But, although Red's clocks begin with event "red E" (same simultaneous plane as "Black E") and end with event "red h", we see the sequence of Red clock readings going into the past along Red's X4 axis world line. The E, a, b, c, ... h designations identify the discrete hyperplanes (planes of simultaneity) in the movement through 4-D Space-Time of Blue as he progresses along his world line.

Twin_TurnD6.jpg


bobc2 said:
There seems to be confusion over the sequence of inertial frames associated with the traveling twin turnaround. I was simply pointing out what I thought was an interesting result for red clock readings as presented in the traveling twin’s sequence of inertial frames. So, here we will not be concerned about the period on the traveling twin's worldline during the turnaround. To avoid any further anguish over discretizing the turnaround, let’s just simplify the analysis by changing the focus away from the turnaround.

In the sketch below we show the same interesting feature by simply comparing readings on what I now show as the brown clock (red in the earlier sketch) as they are presented in the traveling twins two inertial frames, i.e., the purple frame (before turnaround) and the red frame (after turnaround). Notice that Event C presents a brown clock reading in the purple frame at the start of the outgoing trip of the traveling twin (the purple X1 axis represents the outgoing twin's simultaneous space at the start of his trip).

We show the beginning of the twin return trip as Event A (the traveling twin has just completed the turnaround and has started back home, i.e., the Red frame in the sketch). In this twin’s inertial frame the brown clock is presented on the worldline of the Brown frame as Event B.

When the traveling twin reaches Event D, the Event C is simultaneous with that same event (C simultaneous with D) in the twin’s inertial frame.

So, I am simply making the observation that as the traveling twin moves along his worldline, Event C is encountered at the start of the twin’s outgoing inertial frame before the Event B is encountered in the twin’s return inertial frame, even though as the Brown observer moves along his own X4 (time) axis, he (Brown) naturally experiences Event B before Event C. And Events D and C are simultaneous in the twin’s inertial frame. That’s all. No implications are drawn here—just an interesting observation for one to interpret however one pleases. Some may find nothing of interest here.

Twin_Pardx_turnrnd5_zpsca549d99.png

Well you have presented some intertesting observations here. I think there are some implications to be drawn.
Obviously there are some difficult complications regarding a non-inertial frame on several issues but certainly in principle we can assume a single co-accelerating frame for the traveler extending from the initial point to the turnaround.
Disregarding Born rigid acceleration for the turn around itself I for one have no real problem with taking your equivalence of MCIRF's for rough insights. Certainly such a frame would be at all times spatially aligned with the inertial CMRF's

So according to your interpretation at the outset (point O)the traveler at t'=0 at x=0 is simultaneous with event C with brown clock reading t=C at x=C

Then at event D on the travelers worldline at t'=D at x=D the traveler is simultaneous with event C

Later at event A on the traveler worldline at t'=A the traveler is simultaneous with event B at x=B , t=B (B<C)

So looking at this it means that event C is simultaneous with two different times at the same location I.e. at the traveler.
You may have no problem with this but I do.
SO at t'=0 there is a traveler clock at C that reads (C) t'=0 and at event A at t'=A there is also a traveler clock at C reading t'=A
So at a single location and a single instant you have two different observers from the traveler frame with different clock readings.
Quite clearly this is not merely counter intuitive it is simply impossible . Inconsistent with any fundamental conception of spacetime.

Then there is the intersection at event A with the earlier point on the brown worldline B
AT point O the traveler is simultaneous with C yet at later point A he is simultaneous with B which is earlier than C on the brown worldline.
Apparent time travel.
Even more , we can easily describe a situation where a traveler is momentarily co-located with a brown observer on the way out and then after turnaround is again co-located with the same observer at such an earlier time per your interpretation.
Clearly this physical interpretation is open for possible time paradoxes and not a viable possibility.
He receives a message from himself on the way out that he doesn't give the brown observer to forward until after turnaround , etc, etc etc,.

I think you would have to agree that every point in such a frame, even during acceleration,would not only be advancing forward in time but would actually observe all passing clocks also proceeding forward. That these apparent temporal shifts and impossibilities are artifacts of the conventions of Minkowski graphics and a misinterpretation of simultaneity.
They do not conform to any possible reality.
So as the man said"if you eliminate what is impossible , then what you have left ..."

What is quite possible and rational is this:

If we assume that the system clocks could instantaneously be conventionally synchronized during turnaround based on the traveler location as master ,then those outlying clocks would in fact be incremented forward.
So if the traveler clocks are being set ahead, this in a sense is equivalent to the brown clocks falling relatively behind. But the changes are all taking place in the traveler frame and are explicitly the result of human convention.
They are not the result of nor do they result in any change in the relationship between the world lines which both proceed blithely forward..

So it would appear that your illustration in fact provides a reductio ad absurdem argument countering the physical interpretation of planes of simultaneity you were promoting.
 
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  • #164
True, due to our understanding of special relativity, SpaceTime is relative to the observer. Ergo, the speed of light is same within your speed of light (SOL) reference frame as it would be for someone who was traveling much slower. But then, what of Space? Yet this whole frame of reference for mass at light speed is all theoretical since mass cannot exist at the speed of light. Since the concept for mitigating the differences between these two very different reference frames is the basis for this notion of Time slowing down or stopping, let’s explore this theory some more.

There are multiple perspectives to consider for mitagating Time between these two very different frames of reference: A) If as actual rate of Time changes with respect to his acceleration, his reality became part of this slower rate of time, then it would appear to him that his Earth-bound counterparts were milling about at incredible speed in relation to his own. OR B) Consider the SOL traveler is moving at the same rate as he would on Earth, but only the rate of Time changes with respect to his acceleration. In this respect the rate of Time is slowing down consistent with his acceleration, but his movements are still relative to his Earth-bound rate of Time; ergo, he is moving more in less time, or moving faster. Consistent with this notion, he is also able to process more information in less time, or he is thinking faster. Somewhat like a housefly that is able to react and move much faster relative to his frame of reference, the SOL traveler would perceive his Earth-bound counterparts to be moving more slowly or not at all.

The Theory of Relativity favors selection ‘A’ as the SOL traveler’s reality, allowing him to be younger when he returns to Earth. The logic behind this is that as the SOL is measured the same, relative to one’s frame of reference in the rate of time, so must the relative relationship among all of its participants. Subsequently the perspective relationship of man’s speed relative to the actual SOL should remain the same within any reference frame. Consequently if the rate of time slows with acceleration, then so must everything else in that frame of reference do likewise.

But one cannot consider Time without Space, so this brings up another aspect of relativity; i.e. mass increases with acceleration. This would suggest that the mass of the photon becomes greater upon acceleration, as well as everything else in this reference frame. Therefore to suggest that the SOL travelers would age less during the time of their acceleration and would be younger than their Earth-bound counterparts, one must also agree that the SOL travelers should have also retained their increased mass upon return to Earth. Since the most likely form of increased mass would be due to increased density, rather than increased volume, the SOL traveler would be a veritable superman upon his return.
 
  • #165
SJBauer, your post is a mixture of misstatements of SR and speculations which are not justified by SR.

SJBauer said:
SpaceTime is relative to the observer.

No, it isn't. Spacetime is a prime example of something that *isn't* relative to the observer: it's the same 4-dimensional object for everyone.

SJBauer said:
the speed of light is same within your speed of light (SOL) reference frame

There is no such thing as a speed of light reference frame. We have a FAQ on this:

https://www.physicsforums.com/showthread.php?t=511170

SJBauer said:
Since the concept for mitigating the differences between these two very different reference frames is the basis for this notion of Time slowing down or stopping

This might be a valid statement if you are referring to two ordinary inertial frames; but you're not.

SJBauer said:
as actual rate of Time changes with respect to his acceleration

"rate of Time" doesn't depend on acceleration. Time dilation in SR is purely a function of relative velocity. Acceleration only comes into it because it changes relative velocity. See here:

http://math.ucr.edu/home/baez/physics/Relativity/SR/clock.html

SJBauer said:
The Theory of Relativity favors selection ‘A’

The theory of relativity says neither of your "selections" are right. Time dilation is always something that an observer attributes to *other* observers moving relative to him. An observer always experiences his own time as "flowing" normally.

SJBauer said:
allowing him to be younger when he returns to Earth

You appear to be mixing up two different things here: time dilation due to relative motion, and different elapsed proper times along different worldlines that connect the same pair of events. These are different concepts, and you shouldn't confuse them. You can't account for the fact that the traveling twin in the standard twin paradox is younger when the twins meet up again just by using time dilation; there's more to it than that.

SJBauer said:
But one cannot consider Time without Space, so this brings up another aspect of relativity; i.e. mass increases with acceleration.

The "relativistic mass" of an object increases as it moves faster; but just as with time dilation, this depends only on relative velocity, not on acceleration. Acceleration comes into it only because it changes relative velocity.

SJBauer said:
This would suggest that the mass of the photon becomes greater upon acceleration

"Relativistic mass" is equivalent to "energy", and the energy of a photon does change from frame to frame; but again, this is purely due to the change in velocity from frame to frame; acceleration doesn't come into it. The photon's apparent speed does not change (it is always c); but its energy and momentum do.

SJBauer said:
to suggest that the SOL travelers would age less during the time of their acceleration and would be younger than their Earth-bound counterparts, one must also agree that the SOL travelers should have also retained their increased mass upon return to Earth. Since the most likely form of increased mass would be due to increased density, rather than increased volume, the SOL traveler would be a veritable superman upon his return.

This is unjustified speculation; it has nothing to do with SR or the solution of the twin paradox.
 
  • #166
@ SJBauer: I don't know what you mean by a SOL frame of reference. But it is interesting to think about what the change of the rest mass of the traveling twin would be. If the traveling twin was subject to a "pure four-force" (i.e. one where [itex]\vec{f} \cdot \vec{v} = 0 [/itex]) then the change in rest mass is zero. But if he were subjected to a non-pure four-force, then he would generally have some change in rest mass.

Luckily, the electromagnetic four-force is a pure four-force. And I guess we can assume that whatever spaceship he is using, that it is likely to be fundamentally using electromagnetic phenomena (for example, any rocket uses contact force, which is essentially electromagnetic). So unless the traveller has some advanced technology, his rest mass is going to remain unchanged along his journey.
 
  • #167
BruceW said:
it is interesting to think about what the change of the rest mass of the traveling twin would be. If the traveling twin was subject to a "pure four-force" (i.e. one where [itex]\vec{f} \cdot \vec{v} = 0 [/itex]) then the change in rest mass is zero.

This, as you note, is the usual case.

SJBauer said:
But if he were subjected to a non-pure four-force, then he would generally have some change in rest mass.

Can you give a specific example of a non-pure four-force?
 
  • #168
PeterDonis said:
Can you give a specific example of a non-pure four-force?
The only four-force I know of is the electromagnetic four-force. I guess the reason we usually assume the rest mass is constant is because we are usually interested in electromagnetic interactions only. If we consider weak and strong nuclear interaction, then it's a whole different kettle of fish. But I really don't know enough QM to be able to go into that. Anyway, I suppose the term 'four-force' is only used for classical (non-quantum) phenomena. Are there any other kinds of four-force apart from the EM four-force? I don't have a great deal of knowledge about this kind of stuff.
 
  • #169
Austin0 said:
Then at event D on the travelers worldline at t'=D at x=D the traveler is simultaneous with event C

Later at event A on the traveler worldline at t'=A the traveler is simultaneous with event B at x=B , t=B (B<C)
When you say that two events are simultaneous, don't forget to specify the reference frame in which they are simultaneous. In this case, it is two different inertial frames.
 
  • #170
BruceW said:
The only four-force I know of is the electromagnetic four-force.

Four-force is just the 4-D spacetime representation of force. Any force can be represented that way. The key is to look at the effects of the force. The general expression for 4-force is the rate of change of 4-momentum with respect to proper time:

[tex]f^{\mu} = \frac{d p^{\mu}}{d \tau}[/tex]

4-momentum is a 4-vector with components [itex](E, \vec{p})[/itex], and the rest mass is the Minkowski length of the 4-momentum: [itex]m = E^2 - p^2[/itex]. If we look at the force in a frame in which the object starts out at rest before the force is applied, then the 4-momentum starts out as [itex](E, 0)[/itex], so the rest mass m is equal to the starting energy E; we will thus write the starting 4-momentum in this frame as [itex](m, 0)[/itex]. (I'm using units in which c = 1 for simplicity.)

A pure 4-force has a zero dot product with 4-momentum. That means that, in the frame in which the object starts out at rest before the force is applied, the force cannot have a "time" component; it can only have a spatial component. In other words, the 4-force looks like [itex](0, \vec{f})[/itex]. The effect of the 4-force in this frame will be to change the 4-momentum of the object from [itex](m, 0)[/itex] to [itex](\gamma m, \gamma m \vec{v})[/itex], where [itex]\gamma = 1 / \sqrt{1 - v^2}[/itex] and [itex]\vec{v} = \vec{f} \tau / m[/itex], where [itex]\tau[/itex] is the length of the proper time interval during which the force is applied. It should be evident that this will leave the Minkowski length of the 4-momentum unchanged; it will still be m.

An "impure" 4-force has a nonzero dot product with 4-momentum, so its 4-vector in the frame we're using looks like [itex](f_0, \vec{f})[/itex]. The effect of this 4-force will be to change the 4-momentum of the object from [itex](m, 0)[/itex] to [itex](\epsilon + \gamma m, \gamma m \vec{v})[/itex], where [itex]\epsilon = f_0 \tau[/itex] is the "internal energy" added to the object by the force. This "internal energy" is energy added in addition to the kinetic energy added by inducing motion in the object, and it should be evident that this will *increase* the rest mass of the object: the Minkowski length of the resulting 4-momentum is *greater* than m.

The term "internal energy" may make you think of things like heat, and indeed a good example of an "impure" 4-force is friction, which adds heat to the object in addition to changing its speed. Heat shows up as an increase in temperature, and in relativity temperature is part of "rest mass", because mass and energy are equivalent. You may also think of elastic vs. inelastic collisions, which is another good example: forces exerted in purely elastic collisions are pure, whereas forces exerted in inelastic collisions are impure.

BruceW said:
I guess the reason we usually assume the rest mass is constant is because we are usually interested in electromagnetic interactions only. If we consider weak and strong nuclear interaction, then it's a whole different kettle of fish.

Not really, at least not at the level we're looking at here.
 
  • #171
PeterDonis said:
The term "internal energy" may make you think of things like heat, and indeed a good example of an "impure" 4-force is friction, which adds heat to the object in addition to changing its speed. Heat shows up as an increase in temperature, and in relativity temperature is part of "rest mass", because mass and energy are equivalent. You may also think of elastic vs. inelastic collisions, which is another good example: forces exerted in purely elastic collisions are pure, whereas forces exerted in inelastic collisions are impure.
Right, I get it. So we can use a non-pure four-force, depending on the kind of situation we want to model. But we know that fundamentally, any four-force (not going into QM), is EM in nature, and therefore pure.
So an analogous example in classical, non-relativistic mechanics is when we model motion of projectiles near the surface of the earth, we say that there is a downward acceleration of g. So we are saying that vertical momentum is not conserved. But we really do believe that (in classical, non-relativistic mechanics), momentum is conserved, it is just that for the sake of our model, we don't bother to take the motion of the Earth into consideration, so we allow momentum to not be conserved.
 
  • #172
BruceW said:
So we can use a non-pure four-force, depending on the kind of situation we want to model. But we know that fundamentally, any four-force (not going into QM), is EM in nature, and therefore pure.

Another way to put this is that you can always "break down" an impure 4-force into pure 4-forces at a more fundamental level. For example, friction is due to EM interactions between atoms, which are pure; the way the interactions fit together just happens to work out to an impure force at the level of macroscopic objects.

BruceW said:
So an analogous example in classical, non-relativistic mechanics is when we model motion of projectiles near the surface of the earth, we say that there is a downward acceleration of g. So we are saying that vertical momentum is not conserved. But we really do believe that (in classical, non-relativistic mechanics), momentum is conserved, it is just that for the sake of our model, we don't bother to take the motion of the Earth into consideration, so we allow momentum to not be conserved.

Yes, this would be analogous to, for example, only looking at the effect of air resistance on a relativistic projectile, without looking at the effect on the air. When you include the air as well as the projectile, 4-momentum is conserved; but if you just look at the projectile, it isn't.
 
  • #173
Quote by Austin0
So according to your interpretation at the outset (point O)the traveler at t'=0 at x=0 is simultaneous with event C with brown clock reading t=C at x=C

Then at event D on the travelers worldline at t'=D at x=D the traveler is simultaneous with event C

Later at event A on the traveler worldline at t'=A the traveler is simultaneous with event B at x=B , t=B (B<C)

So looking at this it means that event C is simultaneous with two different times at the same location I.e. at the traveler.
You may have no problem with this but I do.
SO at t'=0 there is a traveler clock at C that reads (C) t'=0 and at [event A at t'=A] edit. This should be --event Dat t'=D there is also a traveler clock at C reading t'=D
So at a single location and a single instant you have two different observers from the traveler frame with different clock readings.
Quite clearly this is not merely counter intuitive it is simply impossible . Inconsistent with any fundamental conception of spacetime.

DaleSpam said:
When you say that two events are simultaneous, don't forget to specify the reference frame in which they are simultaneous. In this case, it is two different inertial frames.
well I am just recovering from a long flu and made a serious mistake as I have corrected above.
As for the simultaneity---i was simply taking Bob2c's premise that the planes of simultaneity as indicated by CMRFs in a Minkowski chart are equivalent to 3-D slices of a single accelerated frame at face value and pointing out the impossible consequences of such an interpretation.
I should know from past arguments with Mike_Fontenot on this subject that those who cling to this interpretation are not to be dissuaded by mere details like clocks running backwards or multiple co-locations of disparate spatial points and times.
But there's always hope ;-)
 
  • #174
Austin0 said:
I should know from past arguments with Mike_Fontenot on this subject that those who cling to this interpretation are not to be dissuaded by mere details like clocks running backwards or multiple co-locations of disparate spatial points and times.
That and they seem completely impervious to the fact that it violates one of the very few mathematical requirements that a coordinate chart must match. I don't understand why they "cling" so strongly, when there are so many obvious reasons against it.
 
  • #175
bobc2 said:
For anyone needing a little more background on the space-time sketches and the 4-dimensional universe concept, you can go to this earlier post that outlines the concept, beginning with post #19 (be sure you understand relativity of simultaneity--if not ask questions):

https://www.physicsforums.com/showthread.php?p=4138802#post4138802
I followed your link and found another similar diagram to the one that I asked about in post #161. Here's a clip of the first one:

attachment.php?attachmentid=54923&stc=1&d=1358867640.png


I asked why the blue circles were placed where they were.

Now the clip from the link:

attachment.php?attachmentid=54924&stc=1&d=1358867640.png


Again, I wonder about the placement of the blue circles, why are they placed differently this time?

I really don't understand why you put the blue circles in either place, they have no significance either way to the blue traveler. And what further doesn't make any sense to me is why you draw the blue lines intersecting with the black circles. Now I realize that the slope of the blue lines are indicating simultaneity for the blue traveler no matter where they are placed but you must have some reason to pick these particular lines.

What would make sense to me is if you placed the blue circles at the same increments of Proper Time for the blue traveler as what you picked for the black twin like this:

attachment.php?attachmentid=54925&stc=1&d=1358867876.png


Now you can easily see the symmetry of Time Dilation between the IRF's of the two twins. Or does that matter to what you are trying to convey?
 

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<h2>1. What is special relativity?</h2><p>Special relativity is a theory proposed by Albert Einstein in 1905 that explains how the laws of physics are the same for all observers in uniform motion. It also states that the speed of light in a vacuum is constant and is the same for all observers regardless of their relative motion.</p><h2>2. What is the time paradox in special relativity?</h2><p>The time paradox in special relativity refers to the concept that time can appear to pass at different rates for different observers depending on their relative motion. This can lead to situations where one observer experiences time passing slower or faster than another observer, creating a paradoxical situation.</p><h2>3. How does special relativity affect our understanding of time?</h2><p>Special relativity challenges our traditional understanding of time as a constant and absolute quantity. It suggests that time is relative and can be influenced by factors such as an observer's relative motion and the presence of gravity. This means that time can appear to pass differently for different observers and in different gravitational environments.</p><h2>4. Can the time paradox in special relativity be resolved?</h2><p>While the time paradox in special relativity may seem contradictory, it can be resolved by understanding that time is relative and can be influenced by factors such as relative motion and gravity. This means that the perceived differences in time between observers are not actually paradoxical, but rather a consequence of the theory of special relativity.</p><h2>5. How is special relativity relevant in our daily lives?</h2><p>Special relativity has many practical applications in our daily lives, such as in the functioning of GPS systems and in the development of nuclear energy. It also helps us understand the behavior of particles at high speeds and has led to advancements in fields such as cosmology and particle physics.</p>

1. What is special relativity?

Special relativity is a theory proposed by Albert Einstein in 1905 that explains how the laws of physics are the same for all observers in uniform motion. It also states that the speed of light in a vacuum is constant and is the same for all observers regardless of their relative motion.

2. What is the time paradox in special relativity?

The time paradox in special relativity refers to the concept that time can appear to pass at different rates for different observers depending on their relative motion. This can lead to situations where one observer experiences time passing slower or faster than another observer, creating a paradoxical situation.

3. How does special relativity affect our understanding of time?

Special relativity challenges our traditional understanding of time as a constant and absolute quantity. It suggests that time is relative and can be influenced by factors such as an observer's relative motion and the presence of gravity. This means that time can appear to pass differently for different observers and in different gravitational environments.

4. Can the time paradox in special relativity be resolved?

While the time paradox in special relativity may seem contradictory, it can be resolved by understanding that time is relative and can be influenced by factors such as relative motion and gravity. This means that the perceived differences in time between observers are not actually paradoxical, but rather a consequence of the theory of special relativity.

5. How is special relativity relevant in our daily lives?

Special relativity has many practical applications in our daily lives, such as in the functioning of GPS systems and in the development of nuclear energy. It also helps us understand the behavior of particles at high speeds and has led to advancements in fields such as cosmology and particle physics.

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