From atomic transitions to clockwork gears. So, does this property/constraint makes every clock available to use inherently susceptible to effects of relativistic motion? For example, if you travel at 99% of speed of light with a clock, then there'd be some particle in the clock whose motion, w.r.t you, is also in the same direction, and when added up, it'll surpass 100%. For above situation to be avoided, every particle that makes up the clock will have to be:1. Stationary w.r.t observer, but if this happens, the (frozen) clock can't tell time to the observer. 2. Move in a direction other than that of observer's motion, If this happens, clock can't travel with observer.

Eden Serrano

Eden Serrano

Open question

2022-08-31

From atomic transitions to clockwork gears. So, does this property/constraint makes every clock available to use inherently susceptible to effects of relativistic motion?
For example, if you travel at 99% of speed of light with a clock, then there'd be some particle in the clock whose motion, w.r.t you, is also in the same direction, and when added up, it'll surpass 100%.
For above situation to be avoided, every particle that makes up the clock will have to be:
1. Stationary w.r.t observer, but if this happens, the (frozen) clock can't tell time to the observer.
2. Move in a direction other than that of observer's motion, If this happens, clock can't travel with observer.

Answer & Explanation

sveiparnu

sveiparnu

Beginner2022-09-01Added 5 answers

No, that is not the case. Velocities in relativity add according to the relation
u = u + v 1 + u v / c 2
instead of u = u + v which is what your intuition would tell you. The result of this is that if you are traveling at 99% of the speed of light relative to Observer Bob and some piece of a clock is traveling at any (subluminal) velocity relative to you, Observer Bob will still see the piece of the clock traveling at some speed less than the speed of light, because of time dilation and length contraction.

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