striphe said:I'm having particular amount of difficulty understanding how this outcome arises as the clocks have been synchronised in the Earth frame. Could please explain.
Doesn't it depend on the details of the acceleration profiles of the front and back clocks (e.g. Born rigid vs. simultaneous acceleration in the launch frame vs. something else)?jtbell said:In the ship's new rest frame, the two clocks remain synchronized. In the ship's initial rest frame (the "Earth frame" if it starts from Earth), the clock at the front of the ship is now 0.5 second behind the clock at the rear.
Then you want to study Rindler coordinates:striphe said:I think i was going with born rigid as i was talking about one spacecraft rather than two and run with an on-board perspective.
jtbell said:In the ship's new rest frame, the two clocks remain synchronized. In the ship's initial rest frame (the "Earth frame" if it starts from Earth), the clock at the front of the ship is now 0.5 second behind the clock at the rear.
Your analysis of the second case when the two rockets accelerate identically in the Earth frame up to their final velocity. The clocks will still be synchronised in the Earth frame but in the rocket frame the the rockets will be further apart and the clocks will be out of sync. To synchronise the clocks in the new frame, the rear clock will have to be advanced or the front clock retarded.jtbell said:Right, I was basically assuming Born rigid motion (I think).
It occurred to me after I posted, that if the two clocks are not attached to a spaceship or to each other, and each has its own rocket attached to it, and the two rockets accelerate identically in the Earth frame up to their final velocity, then at the end, the two clocks are still synchronized in the Earth frame, and the distance between them is not length-contracted in the Earth frame (both unlike the case with a Born-rigid rocket). This puts us in the territory of "Bell's spaceship paradox" which has been discussed here extensively.
DaleSpam said:The difference will be
(1+L) T - T = L T
The relativity of simultaneity is a concept in physics that states that the perception of time can vary depending on the relative motion of two observers. This means that events that appear simultaneous to one observer may not appear simultaneous to another observer who is moving relative to the first.
The concept of absolute time suggests that time is constant and unaffected by motion or perspective. However, the relativity of simultaneity proposes that time is relative and can be perceived differently depending on the relative motion of observers.
One example is the famous thought experiment of the twin paradox, where one twin travels at high speeds while the other stays on Earth. When the traveling twin returns, they will have aged less than the twin who stayed on Earth due to the relativity of simultaneity.
The relativity of simultaneity suggests that events that appear to be simultaneous to one observer may not be simultaneous to another. This means that the concept of a single, universal present moment is not valid and can vary depending on perspective. Therefore, the relativity of simultaneity has implications for our understanding of cause and effect, as the perceived order of events may differ for different observers.
The relativity of simultaneity is a fundamental concept in the theory of special relativity, which has greatly influenced modern physics. It has led to a deeper understanding of the nature of time and space, and has helped to reconcile discrepancies between classical mechanics and the laws of electromagnetism. The relativity of simultaneity is also a key concept in the development of theories like general relativity and the concept of spacetime.