Bell's Spaceship Paradox, Born Rigidity, and the 1-Way Speed of Light

In summary, "Bell's Spaceship Paradox, Born Rigidity, and the 1-Way Speed of Light" explores the implications of special relativity through the lens of Bell's spaceship thought experiment, illustrating the paradox that arises when two spacetime-connected spaceships accelerate simultaneously. It delves into the concept of Born rigidity, which describes how objects maintain their shape during acceleration, and highlights the complexities involved in measuring the one-way speed of light, emphasizing that simultaneity is relative. The discussion emphasizes the necessity of considering relativistic effects to fully understand the behavior of moving objects and the nature of light in a relativistic framework.
  • #36
cianfa72 said:
Using whatever physical process to synchronize a such flock of clocks filling the space, does the set of events when they flash a light at a pre-agreed time value always define a spacelike hypersurface in spacetime?
As Nugatory says, the flash events must be spacelike separated from all others, and you need an interpolation process for the spaces between the flashes. It's possible to design a "synchronisation" process maliciously to violate this but most sane processes would be fine.

An example of a valid process is to pick a master clock, have every other clock establish the round trip time for light to the master clock, then have the master clock send out a zeroing pulse, and information on the chosen value of the "fast" speed of light and the direction in which that magnitude is chosen to occur. All clocks can then synchronise themselves to the master clock consistent with the chosen anisotropy.
 
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  • #37
PeterDonis said:
Hyperplanes in spacetime are not just mathematical constructs. Nor is the geometry of spacetime as a whole. That is analogous to the city, and hyperplanes in spacetime are analogous to city streets or blocks--invariant geometric objects.

What is analogous to "simultaneity convention" is drawing map coordinates on the city. Calling a specific set of hyperplanes "simultaneity planes" is defining a simultaneity convention, not defining the hyperplanes themselves; they're there regardless of what you call them.

I'd like to give an enthusiastic thumbs-up to this response.

The overall point is to illustrate the similarities between a map of a 2d surface (assumed for simplicity to be flat), and a space-time diagram. Both are two-dimensional surfaces.

A simultaneity convention on a space-time diagram is like defining the directions "east" and "west" on a map. This would be the "x" axis on a space-time diagram. Selecting the notion of which objects are considered to be "stationary" is like defining the directions "north" and "south" on a map. This would be like the "t" axis on a space-time diagram.

We can do geometry if north-south and east-west are not orthogonal, but - the Pythagorean theorem won't work without modifications.

My point is that we do not HAVE to have north-south and east-west orthogonal to do geometry, but it's a convention, and formulas like the Pythagorean theorem will need to be modified if we make the choice to do something like this. Standardized formulas that are based on the assumption that north-south and east-west were orthogonal would no longer work. But while standard formulas don't necessarily work, it can be done with sufficient care.

Similarly, we do not HAVE to have the time direction, the direction traced out by objects "at rest" on a space-time diagram, orthogonal to the "simultaneity" direction, the direction traced out by what we assume is simultaneous. But again, people do usually assume orthogonality, and some standardized formula would break if one makes this choice.

Space-time geometry is discussed in Taylor and Wheeler, where they present the space-time equivalent of the Pythagorean theorem to the reader. While I am tempted, I won't go into that here, but I will give some references.

Specifically, I'd like to mention 'The Parable of the Surveyor', part of a larger work, the textbook "Space-time Physics" by Taylor and Wheeler. I will note however that while their discussion is illuminating, it does not specifically address "maps" where time and space are not orthogonal, even though it does illustrate nicely some of the basics and motivations of treating space-time geometrically, drawing useful analogies between maps of space and maps of space-time, aka "space-time diagrams".

Google finds https://phys.libretexts.org/Bookshe...etime_Overview/1.01:_Parable_of_the_Surveyors
 
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  • #38
I have one other point to make, that I missed in my last point. That point is this - geometry exists without coordinates. We do not need to draw a grid on a plane in order to be able to do geometry. Special Relativity also has a specific geometry (it is not Euclidean geometry, though). This geometry is also independent of any "grids" we might assume. Arguing about simultaneity conventions is like arguing about the grid layout - it doesn't address the deeper issues, the geometrical ones. The question arises with the one-way speed of light - are we arguing about how to do the geometry of special relativity with oddball grids, or are we arguing about some new geometry that's different from the geometry of space-time of special relativity, known as "Lorentzian geoemtry".
 
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  • #39
Ibix said:
As Nugatory says, the flash events must be spacelike separated from all others, and you need an interpolation process for the spaces between the flashes.
You mean that flash events belonging to the same set must be spacelike separated from each other to define a spacelike hypersurface (the same applies to any set of such flash events). For events in "between" we need an interpolation process to assign them to a spacelike hypersurface.
 
  • #40
cianfa72 said:
You mean that flash events belonging to the same set must be spacelike separated from each other to define a spacelike hypersurface (the same applies to any set of such flash events). For events in "between" we need an interpolation process to assign them to a spacelike hypersurface.
Yes.
 
  • #41
Ibix said:
An example of a valid process is to pick a master clock, have every other clock establish the round trip time for light to the master clock, then have the master clock send out a zeroing pulse, and information on the chosen value of the "fast" speed of light and the direction in which that magnitude is chosen to occur. All clocks can then synchronise themselves to the master clock consistent with the chosen anisotropy.
Take a flock of clocks filling the entire space. Their worldlines form a timelike congruence. Pick one clock as the master clock. Suppose any clock determinates that the round-trip for light to the master clock doesn't change. The master clock send out a zeroing pulse and any clock, upon receiving it, adds half the round-trip time measured for it. This process defines a coordinate time ##t## (one can build a coordinate system where the flock of clocks are "at rest" -- i.e. their worldlines have fixed spatial coordinates and varying ##t##).

Does the above synchronization process define a spacelike hypersurface for events that share a given value of the coordinate time ##t## ?
 
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  • #42
Another point related to this: Born rigid timelike congruence means that the congruence has zero expansion and shear. Is it the same as constant proper distance between any two worldlines in the congruence (i.e. constant round-trip light travel time as measured by any observer along each member of the congruence) ?
 
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  • #43
cianfa72 said:
Born rigid timelike congruence means that the congruence has zero expansion and shear. Is it the same as constant proper distance between any two worldlines in the congruence (i.e. constant round-trip light travel time as measured by any observer along each member of the congruence) ?
Yes.
 
  • #44
Ok, so in the global chart where the Born rigid congruence is at rest (constant spatial coordinates and varying timelike coordinate ##t##), the metric tensor components are such that the solution of differential equation given from ##ds^2=0## for null paths representing the bouncing light pulses sent and received back from any observer in the congruence, gives constant elapsed proper time between the sending and receiving of the same light pulse.
 
  • #45
cianfa72 said:
Ok, so in the global chart where the Born rigid congruence is at rest (constant spatial coordinates and varying timelike coordinate ##t##), the metric tensor components are such that the solution of differential equation given from ##ds^2=0## for null paths representing the bouncing light pulses sent and received back from any observer in the congruence, gives constant elapsed proper time between the sending and receiving of the same light pulse.
You're just repeating the same thing in different words.
 
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  • #46
I'd like to venture a few comments about orthogonality.

To try and put it more plainly, but less precisely (i.e. using popular langauage rather than mathematical language), we need a way to treat time and space as part of a unified whole to say that one is orthogonal to the other. If we regard time as being totally separate from space, I don't think it makes much sense to talk about orthogonality.

To put it more precisely, I would say that in order to talk about time being orthogonal to space, one needs the underlying mathematical structure of special relativity as a 4-dimensional vector space, with an associated vector product rule, usually called an "inner product". Then this vector product defines orthogonal vectors, orthogonality being the condition when the vector product is zero.

This inner product rule of special relativity has many uses, one of the more fundamental ones is to define the "Lorentz Interval" between two events in space-time. Mathematically, this is done by taking the separation vector between the two events (consisting of a spatial separation and a time difference), finding the vector product of this separation with itself, which defines single number.

The important characteristic property of this Lorentz interval is that it is an invariant - it is the same for all observers. The spatial separation and the time separation between two events varies as one chooses different frames of reference (length contraction, time dilation, the relativity of simultaneity), but the Lorentz interval remains the same in all inertial frames of reference. This is discussed in the reference I gave before, Taylor & Wheeler's "Space-Time Physics".

The Lorentz interval of two events connected by a light beam is zero in the theory of special relativity.

The OP may lack and/or not care about this mathematical structure, but this structure is still a part of the thery of special relativity.

There are some physical justifications for using the Einstein clock synchronization system, though, that we can talk about without introducing the underlying mathematical structure of space-time. This is the observation that the Einstein clock synchronization is the unique clock synchronization that makes Newton's laws work in the low velocity limit, as I discussed in a previous post on this thread, post #20, https://www.physicsforums.com/threa...the-1-way-speed-of-light.1064028/post-7101240

Using the usual two-clock notions of velocity, there is only one way of synrhonizing clocks, usually called a "fair" or "isotorpic" synchronization, that makes Newton's laws works.

We could go further afield if we were willing to use the notion of "proper velocity", where there is only one clock, a clock on the moving object, rather than two clocks. This can lead to a formulation of physics where we use "proper" velocities measured by the distance in some frame divided by the time delta of the clock on the moving object, in which case we can write p = m * v_proper.
 
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  • #47
pervect said:
If we regard time as being totally separate from space, I don't think it makes much sense to talk about orthogonality.
If we're thinking about time as being totally separate from space we are - without realizing it - thinking in terms of coordinates in which the t-axis is everywhere orthogonal to the three spatial axes. So yes, it makes no sense to talk about orthogonality - we've already assumed the topic out of the discussion.
 

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