1Introduction to Special RelativityPHYS 1301 F99Prof. T.E. Coan version: 20 Oct ’98IntroductionThis lab introduces you to special relativity and, hopefully, gives you someintuitive understanding of its basic phenomena of “time dilation,” “Lorentz lengthcontraction” and the special way speeds of fast moving objects add together. You willuse a computer simulation during this session that lets you examine the behavior ofsimple objects (rods and clocks) when they travel at very large speeds along a straightline. All of the motion takes place along a straight highway and objects are allowedonly to go forward or in reverse. You will control the speed and direction of motion ofthese objects, subject only to the constraints that the physics of special theoryrelativity imposes on them, first discovered by Einstein in 1905. In case you werewondering, the “special” in special relativity stands for “special case” and signifiesthat the theory of special relativity is a simplification of the more complete theory of“General Relativity.”There are two main points to special relativity. First, imagine you and your labpartner are each in special rooms that contain all of your lab equipment. You look outthe window of your room and see that your partner’s room is moving at some constantspeed with respect to you. She is either approaching or receding at a constant rate.After waving, you both close your respective windows so that neither of you candirectly observe the outside world and perform all sorts of physics experiments. Basedon the results of your experiments, you would not be able tell whether you weremoving or your lab partner was moving. That is, the results of the experiments are thesame whether you are moving or standing still. Similarly, your lab partner would notbe able to tell if she were the moving one or the one at rest. This is the meaning ofrelativity.The second important point is that both you and your lab partner wouldmeasure the speed of light travelling through empty space as having the very samevalue, even though your lab partner is travelling with some speed with respect to you.Although not obvious, this implies that the speed of light is somehow the part of theessential fabric of the physical universe. The speed of light through empty space istypically given the symbol c and has been carefully measured to have the valuec = 3 108× m/sec.Our simulation program automatically calculates all the numbers we require todevelop an understanding of how time, length and speed are affected by SR. Youneed, however, to learn a small number of commands to manipulate the rods andclocks to send them on their way in the appropriate direction and with the appropriatespeed. A detailed list of these commands is included in the lab. You only need tolearn about 10 or so. Finally, it is important to understand that today you will performa simulation of special relativistic effects. The simulation assumes that specialrelativity is correct and lets you explore the consequences of this assumption. The2software does not test whether or not special relativity is correct in the firstplace. What you do today is not really an experiment.Procedure1. Locate the folder Spacetime. The instructor will help you if you can’t locate it.Double click (left mouse button) on the icon Spacetime.2. In the reference material below, read the section The Highway Window. This willexplain to you what you are staring at on the screen. You need to play a bit so thatyou learn a few commands to get something interesting to happen. Read andperform the Tutorial, which is also included in the reference section of this lab.What is most relevant to you is to know how to create rods, clocks, clock stringsand so-called shuttles. Also, you will need to know where to look to find thingslike the speed and position of these things. You do not need to memorize everycommand. The point of the tutorial is to familiarize you with the program. Thiswill probably take 20 minutes or so. Have fun.3. Now we are ready to start by learning how lengths are modified by specialrelativistic effects. Create 4 rods at slightly different positions (x=0.5, 1.0,1.5 and2.0) Give them 9 values of 9 = 0.6,0.8,0.95 and 0.99. I will refer to these rods asrod B (x=0.5) rod C (x=1.0) and so on.4. Question 1. What is the corresponding value 1 for each value of 9? 5. Fill in data table 1 below. On a piece of graph paper, plot 1 v. 9. (This mean thatthe vertical axis should be 1 and the horizontal axis should be 9. Draw a smoothcurve through the 5 points. (You can use the clock at the origin even though itisn’t a rod because we are only interested right now in the relationship between 9and 1.) Question 2. What do you notice about the apparent length of the rods?6. Fill in data table 2 below. Can you make a general statement about the lengths ofobjects when they are moving very rapidly with respect to you?7. This exercise illustrates that if we take into account special relativity, “movingobjects” appear shorter than they do when their length is measured in their ownrest frame. These objects are “Lorentz contracted” by an amount that depends ontheir speed. The greater their speed, the greater their contraction. It is important tounderstand that I am NOT talking about an optical illusion. I am talking about thelength you would measure with a plain old ruler or similar device.38. We now examine how time behaves when we take into account special relativisticeffects. Delete the rods you have previously created and start with a fresh screen.Create 4 clocks (C, D, E and F) at x=0.5, 1.0, 1.5 and 2.0, and give them the 9values of 0.6(clock C), 0.8 (D), 0.95 (E) and 0.99 (F). You should see a total of 5clocks on your screen, including the one (clock B) that is at rest (9=0). Makecertain you are in the reference frame of clock B (that’s the one at rest) andadvance the time on clock B until it reads 10.0 seconds. Examine the times on allthe other clocks. Fill in data table 3. You may find it useful to use the so-calledObject Table found under menu Windows.9. Question 3. What clock seems to be running the slowest? Write down a generalstatement about the rate at which a clock “runs” and the speed of a clock.10. Jump to the reference frame of clock F. Advance clock F until it reads 10.0seconds. Examine the object table. Question 4. Is there any difference betweenthe Object Table now and when you were in reference frame B? Why do youthink