To be clear, for this to mean anything, it has to be a statement in the
frame of reference of the two Earths. It will not be the case that when
the travelling twin reaches Q, they will determine that both Earth
clocks show 24 hours, since, in answer to your later question, the Earth
clocks are not synchronized in the travelling twin's frame.
Sylvia.

No, not as viewed in telescopes (i.e. via light from each earth) nor as
calculated by K' as the time "now".

Rich L.

People often think of special relativity as being a complete description
of events. Popular science descriptions do nothing to dispel this
illusion. But it is not. It is part of a model that includes other
aspects of physics, such as the propagation of light. The complete model
describes the results of measurements, including things that are seen by
way of light that has been emitted by objects at a distance and later
received by a person's eye.

Attempting to construe special relativity alone as describing events
leads to the kind of confusion illustrated by your example. The
travelling twin looks at the belt and infers a remote time on Earth from
it. But that remote time has no physical meaning, and cannot be measured
directly.

Instead, the travelling twin can look at the remote Earth's clock
through a telescope. If the twin observes the belt and infers a time
"now" for Earth, and then waits a time for light to travel the distance
from Earth, the twin would expect to see the previously identified "now"
time through the telescope. But that's not what they would see, because
they've used the wrong model to make their prediction.

Sylvia.

In light of special relativity, starting up that belt is problematic.
First of all,
simultaneous is not a well defined condition for starting because different
observers can have different ideas about when is the same time on both
earths. Second, starting such a long belt will take a long time due to
finite stiffness of the belt. When one earth starts rotating (or engages
with the belt) the motion of the belt will propagate at the speed of sound
in the belt towards the other earth.

Now, in principle, you could start up the belt in such a way that eventually
the entire belt is moving and at constant tension and the two sides of the
belt are synchronized as you are assuming. But that does not establish
a unique synchronization between the two earths. Moving observers,
including the distant observer looking at the belts, will still see different
synchronizations between the two earths depending on the state of motion
of the observer. You can't get around special relativity this way.

Rich L.

No of course. To both "earths" the traveler will be at the same location
X at a given, common (synchro), moment T.

But at that event X,T, traveler's space axis will point toward a past
event of Earth1, and toward a future event of Earth2. So no, they're not
synchronised in a moving system like traveler's.

Their time is running at the same pace though in traveler's system, as
co-members of the same inertial system, obviously.

Yes.
The time axis shows their different times in the Terra system, so they
do 'carry' a different number of rotations. That's precisely why Voyager
has a 'relativistic' POV!
The time unit cT=1 is defined as a 'day', corresponding to one Terra
rotation. So you can count the time for the various points/events.
I've made a few corrections for some point constraints, and clarified
the graph a bit more.

The animation omits the belt time during a half Earth turn, so the belt
is supposed running around a small axis, but at equator rotation speed.
The Earths size is shown though at y=-2.

Another caveat: the belt is also running at 'relativistic' velocities,
so changing its velocity d would impact the relativistic length of the
belt, yet this one is for convenience always equalled to twice the
Earths' proper distance.

On Friday, August 25, 2023 at 12:41:27=E2=80=AFAM UTC-5, Luigi Fortunati wrote:
...
I'll try one last time to make this point. The time "now" for events outside
the light cone, e.g. events that are spatially separated, are not uniquely
defined for different observers.

I must ask what meaning you attach to a time "now" back on earth? It
is not the time you can see, via light, from earth. In fact there is nothing
you can do to interact with earth "now" in any way. The only way to
know what is happening "now" is to wait for that event to enter your
past light cone, at which time you can see it. At that later time you can
know what happened back when you identified a time as "now".

If you want to define some time as "now" by some mechanism like you
describe, that is OK. But the conventional way to define "now" is to
synchronize clocks as described in most any book on special relativity.
That process allows you to define a "now" that conforms with what
we all normally think of as "now". It gives a different result for different
inertial observers, but it gives a result that each observer can make
sense of as "now". That is, if they do some experiment such as send
a time message via light, the result is consistent with special relativity.

There is another factor that you are not taking into account: The
Lorentz contraction of each side of the belt will be different for
moving observers. This may seem as it should be negligible for
such a slow moving belt, but note that magnetic fields are the result
of just such a difference in Lorentz contraction even though the
electrons in a wire are moving at less than 1 mm/second. In the
case of your belt model, a rapidly moving observer will see that
one side of the belt has shrunk compared to the other, and thus
the earth is rotated relative to what the "stationary" observer
calculates.

Rich L.

[[Mod. note -- That's a very clear (and completely correct) exposition.
Thank you!
-- jt]]

It sounds nice, but it is yet wrong. There is no 'rotation' of the two
Earths relative to a traveller along their axis of symmetry.

What *is* true and correct, is that the belts are observed (Lorentz-wise
as well as 'looking'-wise) to advance at different speeds 'back' and
'fro', by the traveller.

Take a look at the graph I proposed before:
https://www.desmos.com/calculator/wreelz925x?lang=nl

For an example, choose b=0.43 (traveller velocity) and d=0.75 (belt
velocity). Choose "Show voyager's POV" (and unchoose "Show Earths'
POV"). Now let the traveller go from Earth1 (left) to Earth2 (right)
with parameter s. Look at the following events:

O. s=0 :
traveller leaves Earth1. Belt check points B (in Earths' POV) leave
their respective Earth, say, B1 and B2. But in traveller's POV, B'1
coincides with B1, but B'2 is already underway, as traveller's x-axis
points to Earths' future.

A. s=0.24 :
Checkpoints B'1 and B'2 cross each other midways (same event for both
traveller and Earths)

B. s=0.364 :
Traveller crosses checkpoint B'2 (heading to the left).

C. s=0.47 :
Checkpoint B'1 reaches Earth2 at the right.
! Immediately a "new" checkpoint B'2bis starts heading to the left! [not
shown]
Checkpoint B'2 is still on its way left.
! In the upper part there is no checkpoint at present!

D. s=0.7 :
Checkpoint B'2 reaches Earth1.
! Immediately, but only just now, a new checkpoint B'1bis starts heading
to the right! [not shown]

E. s=1 :
Voyager reaches Earth2.

From this we can conclude:
The belt running in voyager's direction seems shorter and running at
higher velocity (at times, without checkpoint on it).
The belt running in voyager's opposite direction seems longer and
running at lower velocity (at times, with two checkpoints on it).