A lecture series on Relativity Theory and Quantum Mechanics The Relativistic Quantum World University of Maastricht, Sept 24 – Oct 15, 2014 Marcel Merk.

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A lecture series on Relativity Theory and Quantum Mechanics The Relativistic Quantum World University of Maastricht, Sept 24 – Oct 15, 2014 Marcel Merk

The Relativistic Quantum World Relativity Quantum Mechanics Standard Model Lecture notes, written for this course, are available: Literature used: see lecture notes. Prerequisite for the course: High school level mathematics. Sept 24: Lecture 1: The Principle of Relativity and the Speed of Light Lecture 2: Time Dilation and Lorentz Contraction Oct 1: Lecture 3: The Lorentz Transformation Lecture 4: The Early Quantum Theory Oct 8: Lecture 5: The Double Slit Experiment Lecture 6: Quantum Reality Oct 15: Lecture 7: The Standard Model Lecture 8: The Large Hadron Collider

Lecture 2 Time Dilation and Lorentz Contraction “When you are courting a nice girl an hour seems like a second. When you sit on a red-hot cinder a second seems like an hour. That’s relativity.” -Albert Einstein

Universality of Time “Classical” law of adding velocities Assumes time is universal for all observers. Let us next look at the concept of “simultaneity” in the eyes of Einstein. w w’ w’ = w + v Isaac Newton (1689)Galileo Galilei (1636)

Simultaneity of moving observers Bob sees two lightning strokes at the same time. AC = BC = 10 km. At the time of the lightning strike Alice passes Bob at position D. Also: AD=BD=10 km. Alice sees the same events from the speeding train. By the time the light has travelled 10 km, Alice moved a bit towards B and the light of B reaches her before A. Since also for Alice, the speed of light from AD is the same as that of BD she will conclude that strike B happened before strike A.  Simultaneity of events depends on the speed of the observer! Now, think of Bob and Alice travelling in empty space: who is moving and who is not? Bob Alice

Alternative illustration In the rocket the light reaches the front and back simultaneous, independent of the speed of the rocket. Seen from the outside this is different. But, what is different if we let the rocket “stand still” and the earth move in the opposite direction?

Alternative Explanation

Relativity of Distance A B A B Alice: measure the length of the train by setting simultaneously two tick marks at the track at position A and B (remember: a thought-experiment!) Bob: measure the length of the train by setting simultaneously two tick marks at the track corresponding to the positions A and B. Since Alice and Bob don’t agree on the simultaneity of making the tick marks they will observe a different length. Alice will claim Bob puts tick mark at B too early such that he sees a shorter train: Lorentz contraction.

A clock on a train d mirror light d v: Speed of the train AC B  x’ = v  t’ Reference frame S: Alice on the train Reference frame S’: Bob at the station Bob will see that the ticks of Alice’s clock will slow down. Bob will conclude that time runs slower for Alice than for himself: Time Dilation Light-clock: if d = 1 meter 300 million ticks per second.

Time Dilation S: Alice on the train: S’: Bob at the station: Pythagorean theorem: substitute

Time Dilation S: Alice on the train: S’: Bob at the station:  is called the time dilation factor or Lorentz factor. Pythagorean theorem: substitute

Time Dilation S: Alice on the train: S’: Bob at the station:  is called the time dilation factor or Lorentz factor. Pythagorean theorem: substitute

Time Dilation  Speed v/c For “low” (v<<c) relative speeds: no effect, time stays the same. This we know from every day life. For “high” (v  c) relative speeds: large effect, time runs very slow! This we have never really seen in every day life. Example: A rocket goes at v=0.8 c = 4/5 c : 1 second inside the rocket lasts 1.66 seconds on earth.

Time Dilation: Is it real? Cosmic Muons! Muons: unstable particles with a decay life- time of: t=1.56  s = s (After 1.56  s half of them survive, after 2x1.56  s 25%, etc.) Muon particles are produced at 10 km height (by cosmic rays) with 98% light-speed. Expectation: even travelling at light-speed would take them a time: t = 10 km / km/s = 33  s to reach the ground = 22 x half-life time. Expect: 1 in a million muons arrive on the ground. Also in GPS navigation devices relativity is essential! Measurement: ~ 5% makes it to the ground! Relativity:  Lifetime = 5x1.56  s = 7.8  s Consistent with observation! Since: ½ (33/7.8) = 0.05  5%

Lorentz Contraction mirror light Alice boards a super spaceship with her clock and travels with v=0.98c to a distant star (L=10 light-years). From earth, Bob calculates that the trip takes about 10 years, since: L = v t Bob calculates that since Alice’s clock runs slower, for her the trip takes about 2 years, since   and L = v t = v   t’ Since: 1)Alice and Bob agree on the velocity v 2)Alice and Bob agree on the number of clock ticks 3)For Alice a clock tick does not change Alice observes: L’ = v t’ = 2 light-years! Lorentz contraction: L’ = L /  Distances shrink at high speed!

Relativistic Effects Time dilation: Lorentz contraction: with the relativistic factor: Two definitions: Time in rest frame = “eigen-time” or “proper-time” Length in rest frame = “proper length”

Muon particles revisited From the muon particle’s own point of view it does not live longer. The distance from the atmosphere to the surface has reduced from 10 km to 2 km, such that it does not take 33  s to reach the ground but only 6.8  s. The result is the consistent: Many muons reach the surface! Since also ½ (6.8/1.56) = 0.05  5%

Calvin’s Relativity

Next Lecture… paradoxes! Causality… Travelling to the future…