Special Relativty and Inertial Reference Frames

In summary: It is affected by the gravitational field of the Earth. But for experiments that don't involve the gravitational field of the Earth, the Earth can be considered an inertial reference frame.
  • #1
SudanBlack
5
0
Hi - I've just started having lectures on special relativity at uni. We were talking about inertial reference frames and how these can be characterised by the facts that:
1) They move relative to one another with constant velocity, and
2) Newton's laws operate in inertial reference frames.

Now, we pressume that Newton's laws are true on earth. However, this is not traveling at a constant velocity, since there is a centripetal acceleration towards the sun. So how can we still class the Earth as an inertial reference frame?

Thanks in adnvance. :smile:
 
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  • #2
The "non-inertial" component is VERY weak under most circumstance. Try it yourself.

Sit on a rotating platform and put a ball on the platform. Now, try the same thing with our earth. Put a ball on your desk and see if you observe the same effect. No? Then for all practical purposes, you do not detect this centripetal component due to Earth's orbit around the sun.

Zz.
 
  • #3
SudanBlack said:
Hi - I've just started having lectures on special relativity at uni. We were talking about inertial reference frames and how these can be characterised by the facts that:
1) They move relative to one another with constant velocity, and
2) Newton's laws operate in inertial reference frames.

Now, we pressume that Newton's laws are true on earth. However, this is not traveling at a constant velocity, since there is a centripetal acceleration towards the sun. So how can we still class the Earth as an inertial reference frame?

Thanks in adnvance. :smile:
Your point (2) is not true in SR.
The rotation of the Earth is a more important non-inertial effect than its acceleration. The rotation causes hurricanes, etc. For table top experiments, the Earth can be considered a reasonable inertial frame if the equivalence principle of GR is not applied to g.
 
  • #4
SudanBlack said:
Hi - I've just started having lectures on special relativity at uni. We were talking about inertial reference frames and how these can be characterised by the facts that:
1) They move relative to one another with constant velocity, and
2) Newton's laws operate in inertial reference frames.
I think that both statements are incorrect, or at least they are incomplete.

We can certainly have two inertial reference frames that move relative to each other where the velocity is not constant. This is that case in a gravitational field. And at relativistic speeds it is not Newton's laws but GR that operates in inertial reference frames.

SudanBlack said:
So how can we still class the Earth as an inertial reference frame?
Seems to me a bit of a straw man argument, since who claims it is? :confused:
A spinning sphere is obviously not an inertial reference frame.
 
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1. What is special relativity?

Special relativity is a theory developed by Albert Einstein in 1905 that describes the relationship between space and time in the absence of gravity. It states that the laws of physics are the same for all observers in uniform motion and the speed of light is constant for all observers.

2. What is an inertial reference frame?

An inertial reference frame is a frame of reference in which Newton's laws of motion hold true. In other words, an object at rest will remain at rest and an object in motion will remain in motion at a constant velocity unless acted upon by an external force.

3. How does special relativity affect time and space?

Special relativity states that time and space are not absolute, but are relative to the observer's frame of reference. This means that time and space can appear differently to different observers depending on their relative motion.

4. Can special relativity be observed in everyday life?

Yes, special relativity can be observed in everyday life through phenomena such as time dilation and length contraction. Time dilation is the slowing down of time for an observer in motion, while length contraction is the shortening of an object's length as it moves at high speeds.

5. How is special relativity related to the theory of general relativity?

Special relativity is a special case of the more comprehensive theory of general relativity, which includes the effects of gravity. General relativity states that gravity is the result of the curvature of space-time caused by the presence of mass and energy. It builds upon the principles of special relativity and explains the behavior of objects in the presence of gravitational fields.

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