Quantum Field Theory III

Similar documents
Introduction to Group Theory

Lecture 10: A (Brief) Introduction to Group Theory (See Chapter 3.13 in Boas, 3rd Edition)

Physics 557 Lecture 5

Symmetries, Groups, and Conservation Laws

Symmetries, Fields and Particles. Examples 1.

Particles I, Tutorial notes Sessions I-III: Roots & Weights

Lecture notes for Mathematical Physics. Joseph A. Minahan 1 Department of Physics and Astronomy Box 516, SE Uppsala, Sweden

Symmetries, Fields and Particles 2013 Solutions

4 Group representations

Part III Symmetries, Fields and Particles

2. Lie groups as manifolds. SU(2) and the three-sphere. * version 1.4 *

232A Lecture Notes Representation Theory of Lorentz Group

Physics 129B, Winter 2010 Problem Set 4 Solution

Lecture 5: Sept. 19, 2013 First Applications of Noether s Theorem. 1 Translation Invariance. Last Latexed: September 18, 2013 at 14:24 1

Representations of Lorentz Group

Clifford Algebras and Spin Groups

THE EULER CHARACTERISTIC OF A LIE GROUP

GROUP THEORY PRIMER. New terms: so(2n), so(2n+1), symplectic algebra sp(2n)

Lorentz-covariant spectrum of single-particle states and their field theory Physics 230A, Spring 2007, Hitoshi Murayama

Plan for the rest of the semester. ψ a

Group Theory in Particle Physics

Group Theory Crash Course

Continuous symmetries and conserved currents

CLASSICAL GROUPS DAVID VOGAN

Unitary rotations. October 28, 2014

GROUP THEORY PRIMER. D(g 1 g 2 ) = D(g 1 )D(g 2 ), g 1, g 2 G. and, as a consequence, (2) (3)

Matrix Lie groups. and their Lie algebras. Mahmood Alaghmandan. A project in fulfillment of the requirement for the Lie algebra course

Group theory - QMII 2017

Symmetries, Fields and Particles 2013 Solutions

Basic Concepts of Group Theory

Group Representations

Notes on Group Theory Lie Groups, Lie Algebras, and Linear Representations

LECTURE 25-26: CARTAN S THEOREM OF MAXIMAL TORI. 1. Maximal Tori

2 Lie Groups. Contents

Group Theory - QMII 2017

Chapter 1 LORENTZ/POINCARE INVARIANCE. 1.1 The Lorentz Algebra

PHYSICAL APPLICATIONS OF GEOMETRIC ALGEBRA

Group Theory and the Quark Model

Functional determinants

REVIEW. Quantum electrodynamics (QED) Quantum electrodynamics is a theory of photons interacting with the electrons and positrons of a Dirac field:

PAPER 43 SYMMETRY AND PARTICLE PHYSICS

1. Rotations in 3D, so(3), and su(2). * version 2.0 *

Assignment 12. O = O ij O kj = O kj O ij. δ ik = O ij

Weyl Group Representations and Unitarity of Spherical Representations.

Donoghue, Golowich, Holstein Chapter 4, 6

An homomorphism to a Lie algebra of matrices is called a represetation. A representation is faithful if it is an isomorphism.

These notes are incomplete they will be updated regularly.

Lie Algebra and Representation of SU(4)

Lectures April 29, May

Non-Abelian Gauge Invariance Notes Physics 523, Quantum Field Theory II Presented Monday, 5 th April 2004

Notes on Lie Algebras

1. Matrix multiplication and Pauli Matrices: Pauli matrices are the 2 2 matrices. 1 0 i 0. 0 i

Exercises Symmetries in Particle Physics

Queens College, CUNY, Department of Computer Science Numerical Methods CSCI 361 / 761 Spring 2018 Instructor: Dr. Sateesh Mane.

Lecture 7: N = 2 supersymmetric gauge theory

1: Lie groups Matix groups, Lie algebras

Qualification Exam: Mathematical Methods

Symmetries and particle physics Exercises

Srednicki Chapter 24

LECTURE 16: LIE GROUPS AND THEIR LIE ALGEBRAS. 1. Lie groups

Fulton and Harris, Representation Theory, Graduate texts in Mathematics,

Symmetry Groups conservation law quantum numbers Gauge symmetries local bosons mediate the interaction Group Abelian Product of Groups simple

Assignment 10. Arfken Show that Stirling s formula is an asymptotic expansion. The remainder term is. B 2n 2n(2n 1) x1 2n.

Rotational motion of a rigid body spinning around a rotational axis ˆn;

Physics 251 Solution Set 4 Spring 2013

Group representations

GROUP THEORY PRIMER. New terms: tensor, rank k tensor, Young tableau, Young diagram, hook, hook length, factors over hooks rule

Quantum Theory and Group Representations

Note that a unit is unique: 1 = 11 = 1. Examples: Nonnegative integers under addition; all integers under multiplication.

Lecture 19 (Nov. 15, 2017)

Introduction to relativistic quantum mechanics

MAT265 Mathematical Quantum Mechanics Brief Review of the Representations of SU(2)

Notation. For any Lie group G, we set G 0 to be the connected component of the identity.

7. The classical and exceptional Lie algebras * version 1.4 *

The Homogenous Lorentz Group

Quantum Computing Lecture 2. Review of Linear Algebra

Chapter 2. Linear Algebra. rather simple and learning them will eventually allow us to explain the strange results of

QUATERNIONS AND ROTATIONS

Symmetric Functions and the Symmetric Group 6 B. G. Wybourne

1 g 1,gg 2 xg 1. 2 g 1,...,gg n xg 1. n g 1 } = {gxg 1,gg 1 x(gg 1 ) 1,gg 2 x(gg 2 ) 1,...,gg n x(gg n ) 1 } = {x,g 1 xg 1. 2,...

Topics in Representation Theory: Roots and Weights

Introduction to Modern Quantum Field Theory

The Coleman-Mandula Theorem

A group G is a set of discrete elements a, b, x alongwith a group operator 1, which we will denote by, with the following properties:

Physics 221A Fall 1996 Notes 9 Rotations in Ordinary Space

SPHERICAL UNITARY REPRESENTATIONS FOR REDUCTIVE GROUPS

Lie Theory Through Examples. John Baez. Lecture 1

HYPERKÄHLER MANIFOLDS

5 Irreducible representations

Lie Algebras in Particle Physics

(Ref: Schensted Part II) If we have an arbitrary tensor with k indices W i 1,,i k. we can act on it 1 2 k with a permutation P = = w ia,i b,,i l

CHAPTER 6. Representations of compact groups

4. Killing form, root space inner product, and commutation relations * version 1.5 *

Math 210C. The representation ring

Mic ael Flohr Representation theory of semi-simple Lie algebras: Example su(3) 6. and 20. June 2003

In this lecture we introduce the supersymmetry algebra, which is the algebra encoding the set of symmetries a supersymmetric theory should enjoy.

Parity P : x x, t t, (1.116a) Time reversal T : x x, t t. (1.116b)

1 Smooth manifolds and Lie groups

Lecture 3: Matrix and Matrix Operations

Quantum Symmetries in Free Probability Theory. Roland Speicher Queen s University Kingston, Canada

Transcription:

Quantum Field Theory III Prof. Erick Weinberg January 19, 2011 1 Lecture 1 1.1 Structure We will start with a bit of group theory, and we will talk about spontaneous symmetry broken. Then we will talk about anomalies and grand unification. Then we will cover solitions & duality instantons. Finally we wil talk about supersymmetry. 1.2 Group theory Suppose we have a group G with elements g 1, g 2,... with operation g 1 g 2 = g 3. We require the operation to be associative, there is an identity and every element has an inverse gi = Ig = g, gg 1 = g 1 g = I (1) A group can have finite number of elements or infinite. For the infinite case we can have discrete elements (group of integers) or continuous (real numbers). The most important kind of groups in high energy physics is Lie groups, which is a continuous group. A group element will be labeled by a number of labels g(x 1, x 2,... ) = g(x). We have the group multiplication law g(x)g(y) = g(z) (2) where z is a continuous differentiable function of x and y. We can also think of the Lie group as a manifold. The dimension of the manifold, which is also the dimension of the Lie group, is equal to the number of parameters necessary to specify each group element. The manifold can be compact or non-compact. For example, a rotation group is compact, and if you keep rotation you will come back to the original position. However the Lorentz group is not compact, and you can boost forever. The Lorentz group will likely be the only non-compact group that we will make reference to. References can be found in the book by Georgi. Another one written by Gilmore. Let s look at some examples. Consider the group SO(N). This can be defined as the group of N N orthogonal matrices with determinant 1, or can be defined as the rotation group in N dimensions. From N N we have N 2 parameters, but from orthogonality we have the constraint R ij R jk = δ ik (3) This gives N conditions when i = k and N(N 1)/2 conditions when i k. So in the end we have N(N 1)/2 free parameters. So the group has dimension N(N 1)/2. Now if we erase S and consider 1

O(N). It has the same dimension as SO(N) but has two disconnected parts. The one containing identity is the same as SO(N). Now we consider U(N) which is the group of complex N N unitary matrices. Because it is unitary we have det U = 1. By the same argument as above we can find the dimension of the group to be of dimension N 2. Now if we consider SU(N), then we should have det U = 1. This subtracts one parameter as the determinant is a continuous variable. So the dimension of SU(N) is N 2 1. The Lorentz group, which is non-compact, has 3 boosts and 3 rotations. So this has 6 dimensions. These are the examples we want to consider. But these groups are not all distinct. We can write an element in U(1) as e iθ, and an element in SO(2) as a matrix with parameter θ. These two groups are essentially identical U(1) = SO(2) (4) We also have relations between SU(2) and SO(3). Each element in SO(3) corresponds to 2 elements in SU(2). In general we have the group Spin(N) which has two to one correspondence with SO(N). We also have correspondences between Lie groups and Lie algebras. A Lie algebra is related to the neighborhood of identity in the Lie group. If we think of the Lie group as a manifold, then the structure around the identity is almost enough to determine the whole group (apart from some double-cover things). To do this we think of the group as group of matrices and choose the coordinates so that the identity is I = (0, 0,... ). Near identity we have g = I + i j α j T j + O(α 2 ) (5) The α s are the coordinates and T j are generator matrices. The factor of i is just convention. In SO(3) the conventional generators will be the angular momenta J 1, J 2, J 3. An important result in the theory of Lie groups is that any element continuously connected to I can be written as g = exp (i ) α j T j (6) Now let s get some conditions on the T j generators. Let s look at the element g = e iλta e iλt b e iλta e iλt b (7) We assume λ 1. By group multiplication law this is an element of the group, so we can write ( g = exp i ) α k T k k (8) Now we need to do some manipulations ) g = e (e iλta iλta e iλt b + [e iλt b, e iλta ] e iλt b = I + e iλta [e iλt b, e iλta ]e iλt b (9) Now we can expand everything for small λ and keep up to terms of order λ 2, we get g = I + [iλt b, iλt a ] + O(λ 3 ) = I + λ 2 [T b, T a ] + O(λ 3 ) (10) Now this should be a group element, so the commutator of two generators should be a linear combination of all the generators [T a, T b ] = if c ab T c (11) 2

It is apparent that f c ab = f c ba. If we choose T s correctly then f abc will be completely antisymmetric. In SO(3) for conventional generators we have f abc = ε ijk. The f s are called structure constants. Now we come back to Lie algebra. A Lie algebra is defined to be a vector space with a bracket operation satisfying that i[a, B] is inside the algebra for any A, B in the algebra, and we have to satisfy the Jacobian identity [A, [B, C]] + [B, [C, A]] + [C, [A, B]] = 0 (12) The Poisson bracket is a form of Lie algebra operation {f(q, p), g(q, p)} = ( f g f ) g q j j p j p j q j (13) It satisfies the Jacobian identity but it is nontrivial to show. If we consider hermition matrices, in general (AB) AB, but the commutator (i[a, B]) = i[b, A ] = i[a, B] (14) So the commutator is inside the Lie algebra. The structure constants determines the whole algebra, so the algebras for SO(3) and SU(2) are the same. Let s consider SO(N). The elements satisfy R T R = I. So we have ( ) I + i j α j Tj T +... I + i k α k T k +... = I + i α j (T j + T T j ) + = I (15) So the generators must be N N antisymmetric matrices. This also applies to O(N). Same procedure shows that generators of U(N) are N N hermitian matrices. Now for SU(N) we need a condition on the determinant det [ e iα jt j ] = 1 = det [I + iαj T j +... ] = 1 + iα j Tr T j (16) So the generators are traceless. We can define direct products of different groups G = H K, with elements g = (h, k) and product g 1 g 2 = (h 1 h 2, k 1 k 2 ). The dimension is obviously the sum of two dimensions. We can choose a basis where the generators of G is the union of generators of H and generators of K with the two subsets commuting with each other. Conversely if the set of generators {T j } can be written as { } { } {T j } = t a (1) t b (2) (17) with the two subsets mutually commuting then any g can be written as g = e iα jt j (1)e iβ kt k (2) (18) Then locally G = H K, G is a direct product. For example we consider SO(4), the generators are J ij = J ji. Rotations are associated with a plane. We can define two sets of generators H i = 2 (J 23 + J 14 ), 1 2 (J 31 + J 24 ), 1 } 2 (J 12 + J 34 ), K i = 2 (J 23 J 14 ), 1 2 (J 31 J 24 ), 1 } 2 (J 12 J 34 ) 3 (19)

We can check that the H i commute with K j and they individually form SO(2) algebra. So the SO(4) algebra is the same as SU(2) SU(2) algebra. The correspondence looks like ( e iα H, e iβ K) e iα H e iβ K (20) Suppose we rotate by 2π we can have ( I, I) or (I, I) on the left side, but only I on the right side. So we have the relation SO(4) SU(2) SU(2) = (21) Z 2 Similar procedure can be carried out for the Lorentz group SO(3, 1). Because the commutation relation for the SO(3, 1) algebra is obtained by just replacing the δ ij in the commutation relation of SO(4) by g µν, the corresponding modification in H and K is just adding i in front of all the J with index 1: H i = 2 (J 23 + ij 14 ), 1 2 (ij 31 + J 24 ), 1 2 (ij 12 + J 34 ) }, K i = 2 (J 23 ij 14 ), 1 2 (ij 31 J 24 ), 1 2 (ij 12 J 34 ) (22) Now because there is a factor of i in front of some of the original generators, we would expect the exponential e iα jh j to have some non-periodic behavior in one direction. This is what makes the Lorentz group noncompact. A group is simple if there is not subgroup N such that gng 1 = N. There is no normal subgroups. A semisimple group is a group without an abelian normal subgroup. A Lie group is simple if it can t (even locally) be written as a product H K. A Lie group is semisimple if it has no U(1) factors. SO(3) is simple and semisimple. SU(4) SU(2) SU(2) is semisimple but not simple. U(N) U(1) SU(N) is neither simple nor semisimple. Any compact Lie group can be build up from simple compact Lie groups either by direct products or by direct products with some quotients. So if we know the simple compact groups we know all the compact groups. So we will only care about simple Lie groups. These are classified as SU(N), SO(N), Sp(N), E 6, E 7,... Now we consider group representations. We associate with every group element a matrix D(g) which satisfies D(g 1 )D(g 2 ) = D(g 1 g 2 ) (23) Two g s can have the same matrix, so there is aways the trivial representation D(g) = 1 which exists for any group. The dimension of the representation is the dimension of D which has nothing to do with the dimension of the group. Matrices correspond to linear transformations, so an r-dimensional representation corresponds to a set of r objects that mix under these linear transformations. Two representations are equivalent D (1) (g) = D (2) (g) if for every g we have D (1) (g) = SD (2) (g)s 1 (24) and S does not depend on g. This is just like changing basis. A unitary representation is where all D(g) are unitary matrices. A finite or compact group implies that all representations are equivalent to a unitary representation. A noncompact group is not so, i.e. we can find representations not equivalent to unitary ones. The Lorentz group has unitary representations, but they are infinite dimensional. It also has finite dimensional representations, but they are not unitary. A reducible representation means that by a change of basis we can write [ ] D(g) = S 1 D (1) (g) D (2) (g) S (25) } 4

so the representation is equivalent to a block-diagonal one. We can build up all representations this way, so we will be only interested in irreducible representations. For example, for SO(3) we have vectors which transform like V i V i = R ij V j (26) But we also have rank-2 tensors which transform like T ij T ij = R ik R jl T kl (27) But we can write any tensor into symmetric part and antisymmetric part. A symmetric tensor remains symmetric under rotation, so does the antisymmetric tensor. It can be further decomposed because trace is invariant under rotation. So T ij = T δ ij + A ij + S ij (28) 5

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback