Option A Relativity A1 The beginnings of relativity
Learning objectives
It is said that Albert Einstein, as a boy, asked himself what would happen if he held a mirror in front of himself and ran forward at the speed of light. With respect to the ground, the mirror would be moving at the speed of light. Rays of light leaving young Einstein’s face would also be moving at the speed of light relative to the ground. This meant that the rays would not be moving relative to the mirror, hence there should be no reflection in it. This seemed odd to Einstein. He expected that looking into the mirror would not reveal anything unusual. Some years later, Einstein would resolve this puzzle with a revolutionary new theory of space and time, the theory of special relativity.
R Use reference frames R Understand Galilean relativity
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with Newton’s postulates for space and time R Understand the consequences of Maxwell’s theory for the speed of light R Understand how magnetic effects are a consequence of relativity
A1.1 Reference frames
In a physics experiment, an observer records the time and position at which events take place. To do that, she uses a reference frame.
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A reference frame is set of coordinate axes and a set of clocks at every point in space. If this set is not accelerating, the frame is called an inertial reference frame (see Figure A.1).
So if the ‘event’ is a lightning strike, an observer will look at the reading of the clock at the point when lightning struck and record that reading as the time of the event. The coordinates of the strike point give the position of the event in space. So, in Figure A.2, lightning strikes at time t = 3 s at position x = 60 m and y = 0. (We are ignoring the z coordinate.) The same events can also be viewed by another observer in a different frame of reference. Consider, therefore, the following situation involving one observer on the ground and another who is a passenger on a train.
x
Figure A.1 A two-dimensional reference frame. There are clocks at every point in space (only a few are shown here). All clocks show the same time.
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ft lightning strikes at x = 60 m and t = 3 s
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0 3 9
0 3 9
0 3 9
0 3 9
0 3 9
0 3 9
0
3 9
3
6
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6
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x=0
x = 10
x = 20
x = 30
x = 40
x = 50
x = 60
x = 70
x = 80 m
Figure A.2 In this frame of reference the observer decides that lightning struck at time t = 3 s at position x = 60 m.
PHYSICS FOR THE IB DIPLOMA © CAMBRIDGE UNIVERSITY PRESS 2014
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A RELATIVITY
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03/09/2014 08:23