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Physics 2170 – Spring 20091 Einstein’s theory of special relativity First homework assignment is online. You.

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Presentation on theme: "Physics 2170 – Spring 20091 Einstein’s theory of special relativity First homework assignment is online. You."— Presentation transcript:

1 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20091 Einstein’s theory of special relativity First homework assignment is online. You will need to read about time dilation (1.8) to answer problem #3 and for the definition of for problem #4. First problem solving session will be Tuesday 3-4 and 5-6. Homework is due Wednesday at 12:50pm in wood box in physics help room (G2B90). No class on Monday (MLK) Announcements: Today we will introduce the special relativity postulates and think about simultaneity. Albert Einstein (1879—1955):

2 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20092 From Maxwell’s equations, light is an electromagnetic wave with speed: Conventional wisdom: Waves must have a medium to travel in – sound in air, tsunami in water, etc. Therefore it was believed light traveled in stationary ether where the speed was 299792458 m/s. If the ether exists, it is an incompressible, invisible, and non-viscous medium which permeates the universe (like The Force).

3 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20093 The ether Suppose the earth moves through the fixed ether with speed v. A light wave traveling at speed c with respect to the ether is heading in the opposite direction. According to Galilean relativity, what is the speed of the light wave as viewed from the earth? A) c B) c + vC) c − v vc Clicker question 1 Set frequency to DA

4 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20094 Boat travels back and forth across river with width How long does it take to complete each trip? Up & down river: Across river: Boat travels at speed on a river with current at velocity Boat travels up and down a river a distance of You get different results depending on the route taken!

5 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20095 Michelson-Morley experiment in 1887 to see ether effect Measure speed of light in 2 perpendicular directions Floated in mercury so could rotate to see effect. Also took data at different times of year. Earth goes around sun at 30 km/s – must be going through ether Should see ether flow as small as 1 km/s and saw nothing!

6 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20096 Present View: There is no ether Electromagnetic waves are special. A time-changing electric field induces a magnetic field, and vice-versa. A medium (“ether”) is not necessary.

7 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20097 Einstein’s relativity postulate #2 The speed of light is the same in all inertial frames of reference.

8 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20098 Suppose the earth moves through space with speed v. A light wave traveling at speed c with respect to faraway stars is heading in the opposite direction. According to Einstein’s relativity, what is the speed of the light wave as viewed from the earth? A) c B) c + vC) c − v vc Clicker question 2 Set frequency to DA

9 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 20099 Time to talk about time Measuring time in different frames Synchronization of clocks What time is it? How do you know?

10 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200910 Clicker question 3 Set frequency to DA Q. The speed of light in a vacuum is 3.00 x 10 8 m/s. About how long does it take light to travel the length of your arm? A. 1 ms (10 -3 s) B. 1 μs (10 -6 s) C. 1 ns (10 -9 s) D. 1 ps (10 -12 s) E. 1 fs (10 -15 s) Speed of light c = 3.0 X 10 8 m/s = 0.3 m/ns = 300 m/  s (Note also, c ~ 1 foot/ns, which is something I use all the time)

11 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200911 Clicker question 4 Set frequency to DA Q. In a given reference frame, the time at which in event takes place is given by: A. The time an observer at the origin of the reference frame observes the event. B. The time anyone in the reference frame observes the event. C. The time given by a local observer’s clock located at the event. D. The time given by a properly synchronized local observer’s clock located at the event. We have argued that to describe a physical event, we must specify both where it is (in some inertial coordinate system) and what time it occurs (according to some clock). But which clock?

12 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200912 More on reference frames An observer at (0,0) has a clock; events there are covered. An observer at (3m,2m) had better have a clock, too, if you want to know about events there. And, the two clocks had better show the same time.

13 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200913 Synchronizing clocks At the origin, at three o’clock, the clock sends out a light signal to tell everybody it’s three o’clock. Time passes as the signal gets to the clock at x = 3m.... -3 -2 -1 0 1 2 3... When the signal arrives, the clock at x=3m is set to 3:00 plus the 10 ns delay. This is a properly synchronized clock

14 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200914 Simultaneity in one frame... -3 -2 -1 0 1 2 3... From the local observers we can know when and where events really happen, even if I don’t find out until later (when the event reports get filed). Using this procedure, it is now possible to say that all the clocks in a given inertial reference frame read the same time. So we can have observers anywhere in the universe (in the reference frame) with a properly synchronized clock Even if I don’t go out there to check it myself.

15 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200915 Simultaneity Now we’ve got clocks under control (in one inertial frame) Do events occur at the same time (i.e., simultaneously?) Says who?

16 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200916 Two firecrackers sitting on the ground explode. Lucy, sitting on the ground halfway between the firecrackers, sees each explosion at the same time. She knows the location of each explosion and reasons that they exploded at the same time. Ricky is sitting on the ground next to firecracker 2. According to Ricky, which firecracker explodes first? A.Both explode at the same time B.Firecracker 1 explodes first C.Firecracker 2 explodes first 12 LucyRicky Clicker question 5 Set frequency to DA Note that Ricky knows how far away each firecracker is so the fact that he sees #2 first does not mean he thinks #2 explodes first.

17 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200917 Two firecrackers sitting on the ground explode. Lucy, sitting twice as close to #2 as #1, sees the two explosions at the same time. Which firecracker explodes first in her reference frame? A.Both explode at the same time B.Firecracker 1 explodes first C.Firecracker 2 explodes first 12 Lucy Clicker question 6 Set frequency to DA If Lucy sees the light from both at the same time and knows that #1 is further away, it must have exploded first. Anyone else in her reference frame will come to the same conclusion!

18 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200918 Simultaneity in two frames... -3 -2 -1 0 1 2 3... A second frame has its own clocks, and moves past me. What happens now?... -3 -2 -1 0 1 2 3... v

19 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200919 Lucy L R After the firecracker explodes, a spherical wave front of light is emitted. Now Lucy is the middle of a railroad car, and sets off a firecracker. Light from the explosion travels to both ends of the car. Which end does it reach first? Reaches both ends at the same time. This wave front reaches the two ends at the same time. Note that Lucy doesn’t find out until later when the observers at each end with their synchronized clocks report in. But that is an unimportant detail.

20 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200920 Ricky Lucy Ricky is standing still next to the tracks, watching the train move to the right. According to Ricky, which end of the train car does the light from the explosion reach first? LR In Ricky’s frame, these events are not simultaneous. v Clicker question 7 Set frequency to DA A. Both ends at the same time B. Left end (L) first C. Right end (R) first Really, they are not simultaneous!

21 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200921 Lucy v... -3 -2 -1 0 1 2 3... Ricky Suppose Lucy’s firecracker explodes at the origin of Ricky’s reference frame. LR

22 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200922 Lucy v... -3 -2 -1 0 1 2 3... Ricky The light spreads out in Ricky’s frame from the point he saw it explode. Because the train car is moving, the light in Ricky’s frame arrives at the left end first. LR Local observers at ±2.5 in Ricky’s frame say the light arrived there at the same time but at this point only the left end of the car is at −2.5, the front end is way off at 6 or so.

23 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200923 Lucy... -3 -2 -1 0 1 2 3... Ricky Sometime later, in Ricky’s frame, the light catches up to the right end of the train (the light is going faster than the train). v LR

24 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200924 Simultaneity is relative! Given two events located at different positions: 1) light hits the right end of the train car 2) light hits the left end of the train car Lucy finds that the events are simultaneous. Ricky (in a different reference frame) finds that they are not simultaneous. And they’re both right!

25 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200925 Lucy v... -3 -2 -1 0 1 2 3... Ricky Suppose Lucy’s firecracker is just slightly toward the right end of the train, so slightly that Ricky still measures the light hitting the left end first. According to Lucy, which end gets hit first? LR Clicker question 8 Set frequency to DA A. Both ends at the same time B. Left end (L) first C. Right end (R) first

26 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200926 The order of events isn’t even absolute Not only can observers in the two frames not agree whether the events at different locations are simultaneous, they may not even agree which event came first. And that’s the relativity of simultaneity.

27 http://www.colorado.edu/physics/phys2170/ Physics 2170 – Spring 200927 So, the proper time of a clock keeping time is the time in the reference frame where the clock is not moving. In an inertial reference frame in which the clock is moving, the moving clock will be slower by a factor of : Executive Summary of Time Dilation The proper time is the time between two events in the reference frame where both events take place at the same location. We will cover time dilation for real next Wednesday. andwhere

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