Special Relativity: Comparing Lengths in Parallel Motion

In Summary, the pole-barn paradox demonstrates that the motion of a rod is length-contracted in different frames of reference.
  • #1
RohanJ
18
2
In Introduction to special relativity by Resnick,there is a thought experiment to compare lengths perpendicular to relative motion as given in the below image.
What if we try to perform such an experiment to compare lengths parallel to relative motion?
Suppose there are two horizontal rods moving relative to each other along x -x' axis. If both the rods have a marker at each end,then what will happen when they pass each other?
Screenshot_2019-11-11-22-21-53-665_com.google.android.apps.docs.png
 
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  • #2
A measurement of length requires simultaneous measurements of the position of both ends. When the rods are vertical, all four ends of the rods are at the same ##x## coordinate at the same time in both frames.

If the rods are horizontal, then the two ends are spatially separated along the direction of motion. And this makes all the difference. In this case, both rods will be contracted when measured in the other frame.
 
  • #3
RohanJ said:
Suppose there are two horizontal rods moving relative to each other along x -x' axis. If both the rods have a marker at each end
If you google for "pole-barn paradox" you will find many good explanations of what's going on here.

So we have lab assistants, one stationed at each end of the two rods (that's four total) and holding loaded paintbrushes. They have been all been instructed to swipe out with their brushes to mark whatever is passing at the moment that the two origins coincide.
then what will happen when they pass each other?
Both rods will have one mark, at the origin, made by the lab assistant stationed at the origin end of the other rod. The two lab assistants at the non-origin ends of the two rods will find that at the moment that the origins coincide they are facing just empty space so they don't make any mark. This result is consistent with the moving rod being length-contracted no matter which rod we choose to consider to be at rest.

There is no contradiction because of the relativity of simultaneity. The events "origins coincide" and "lab assistant at end of rod A swipes their brush" happen at the same time in the frame in which rod A is at rest, but not the frame in which rod B is at rest, and vice versa. If you are not already comfortable with relativity of simultaneity, you'll want to learn about it (google for "Einstein train simultaneity") because it is essential to understanding how special relativity is consistent.
 
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FAQ: Special Relativity: Comparing Lengths in Parallel Motion

What is special relativity?

Special relativity is a fundamental theory in physics that explains the relationship between space and time. It was developed by Albert Einstein in the early 20th century and has been extensively tested and confirmed through experiments.

What is the concept of parallel motion in special relativity?

In special relativity, parallel motion refers to the movement of two objects that are moving in the same direction at a constant speed relative to each other. This concept is important because it allows us to compare the lengths of objects that are moving at different speeds.

How does special relativity affect the measurement of lengths in parallel motion?

According to special relativity, the length of an object will appear shorter when it is moving at high speeds relative to an observer. This effect, known as length contraction, is a result of the distortion of space and time at high speeds.

Can special relativity be applied to everyday situations?

Yes, special relativity has many practical applications in our daily lives. For example, it is used in the design of GPS systems, which rely on precise measurements of time and space to function accurately. Special relativity also helps us understand the behavior of particles in accelerators and the effects of high-speed travel on astronauts.

What are the implications of special relativity for our understanding of the universe?

Special relativity has revolutionized our understanding of the universe by showing that space and time are not absolute, but are relative to the observer's frame of reference. It also paved the way for the development of Einstein's theory of general relativity, which describes the relationship between gravity and the curvature of spacetime.

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