1 symmetry and physics. 2 1.origin 2.greeks 3.copernicus & kepler 4.19th century 5.20th century

1

Symmetry and Physics

2

1. Origin

2. Greeks

3. Copernicus & Kepler

4. 19th century

5. 20th century

3

1. Origin of Concept of Symmetry

4

5

6

Painting

Sculpture

Music

Literature

Architecture

7

8

9

10

11

12

2. Greeks

13

14

Harmony of the Spheres

Dogma of the Circles

15

3. Copernicus (1473-1543)

Kepler (1571-1630)

16

Six planets:

Saturn, Jupiter, Mars,Earth, Venus, Mercury

17

Mysterium Cosmographicum

1596

18

19

One of the methods now to find reasons of some observed regularity:

20

(a) Choose some mathe-matical regularity resulting from symmetry require-ments.

(b) Match it to observed regularity.

21

22

•Discussed why snow flakes are 6-sided

•Albertus Magnus: +1260

•In China: -135

23

24

25

But no effort to try to explain why.

26

4. 19th Century

Groups and Crystals

27

Galois (1811-1832)

28

Concept of groups is the mathematical representation of concept of symmetry.

29

Symmetry

and invariance

30

31

32

33

A 90° rotation is called a 4-fold rotation.

34

It will be denoted by 4.

It is an invariant element of the graph.

35

36

37

38

39

40

41

3 dimensional 230 (1890)

2 dimensional 17 (1891)

4 dimensional 4895 (~1970)

42

43

44

5. 20th Century

45

5.1 Symmetry applied to concepts of space and time

46

Special Relativity

1905

Lorentz Symmetry

47

General Relativity

1916

Very Large Symmetry

48

5.2 Symmetry applied to atomic, nuclei, particle properties

49

Quantum Numbers, spin, parity

50

51

Great importance in most branches of physics 1920

52

Symmetry = Invariance

Conservation Laws

(Except for discrete symmetry in classical mechanics)

Other Consequences

Quantum Numbers

Selection Rules

(In quantum mechanics only)

53

54

55

56

57

5.3 Symmetry applied to structure of interactions (forces).

58

Maxwell Equations have,

beyond Lorentz Symmetry,

59

Another symmetry:

Gauge Symmetry

60

In 1915-1916 Einstein published his general relativity, making gravity a geometrical theory. He then emphasized that EM should also be geometricized.

61

H. Weyl (1885 – 1955) took up the challenge and proposed in 1918 a geometrical theory of EM.

62Hermann Weyl (1885-1955)

63

Levi–Civita and others have developed the idea of “parallel transport”

64

.A

65

On a curved surface, the parallel transported vector may not come back to its original direction.

66

Weyl asked, if so

“Why not also its length?”

67

“Warum nicht auch seine Länge?”

68

B

A

x dexp

A

B

.

.

Proportionalitätsfaktor

69

And pointed out that some changes inleaves his theory invariant, while the EM vector potential has similar properties.

,A

70

So he put

eA

71

Connecting EM with

geometry

72

Masstab InvarianzMeasure InvarianceCalibration InvarianceGauge Invariance

73

Weyl submitted his paper to the Prussian Academy. The editors, Planck and Nernst, asked for the opinion of Einstein:

74

With his penetrating physical intuition, Einstein objected.

75

A B

76

Einstein’s postscript:

“the length of a common ruler (or the speed of a common clock) would depend on its history.”

77

QM came to the rescue.

78

1926-1927

Fock, London

)d(expdexp xiAxA

79

Proportionality Factor

Phase Factor

80

Gauge Theory

Phase Theory

81

With gauge phase,

how about Einstein’s objection?

82

Phase difference at B

A B

83

1959 Aharonov-Bohm

A B

84

Chambers used a tapered magnetic needle instead of a long solenoid and claimed he had seen the A-B effect.

85

But the leaked flux

from his needle

caused objection.

86

Finally in the mid 1980s, Tonomura et. al. quantitatively proved the A-B effect. Thus introducing experimentally topology into fundamental physics.

87

88

89

Weyl’s idea was generalized in 1954

90

Searching for a Principle for Interaction

91

First Motivation:

Many new particle. How do they interact?

92

Second Motivation:

“the electric charge serves as a source of electromagnetic field; an important concept in this case is gauge invariance ...”

93

“We have tried to generalize this concept of gauge invariance to apply to isotopic conserva-tions.”

94

Third Motivation:

“It is pointed out that the usual principle of invariance under isotopic spin rotation is not consistent with the concept of localized fields.”

95

Maxwell Non AbelianGauge Theory

,, bbF kjijk

i,

i,

i bbcbbF

JF ,ikji

jki

, JFbcF

96

Beautiful and Unique Generalization.But too much symmetry to agree with experiments in 1954 to late 1960s.

97

Symmetry Breaking

98

Algebraic Symmetry.

But broken symmetry in observation.

99

Symmetry Dictates

Interaction

100

Symmetry Invariance

—

Conservation Laws

Gauge Symmetry

Symmetry Dictates Interaction

Other Consequences

QuantumNumbers

Selection Rules

StrongForce

︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴

︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴︴ Electromagnetic

Force

Weak Force

GravityForce

101

Usual Symmetry Gauge Symmetry

Equation Equation

Sol. Sol. Sol. Sol. Sol. Sol.

Different Physics Same Physics

102

Supersymmetry 1973

Supergravity 1976

Superstrings 1984