Representation Theory

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Presentation transcript:

Representation Theory PHY 745 Group Theory 11-11:50 AM MWF Olin 102 Plan for Lecture 3: Representation Theory Reading: Chapter 2 in DDJ Some details of groups and subgroups Preparations for proving the “Great Orthgonality Theorem” 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

1/18/2017 PHY 745 Spring 2017 -- Lecture 3

1/18/2017 PHY 745 Spring 2017 -- Lecture 3

A subgroup S is composed of elements of a group G which form a group Groups and subgroups A subgroup S is composed of elements of a group G which form a group A subgroup is called invariant (or normal or self-conjugate) if 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Example of a 6-member group E,A,B,C,D,F,G 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Note that this group (called P(3) in your text) can be also described in terms of the permutations: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Invariant subgroup 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Groups of groups – The factor group is constructed with respect to a normal subgroup as the collection of its cosets. The factor group is itself a group. Note that for a normal subgroup, the left and right cosets are the same. Group properties: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Multiplication table for factor group: P(3) example: Factor group Multiplication table for factor group: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Representations of a group 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Example: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

The great orthogonality theorem on unitary irreducible representations 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Example: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Special types of matrices -- unitary 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Special types of matrices -- Hermitian Here the diagonal elements are real. 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

In this case the diagonal elements have modulus unity. Digression: Note that unitary matrices themselves can also be put into diagonal form with a unitary similarity transformation. Last week we had the example: In this case the diagonal elements have modulus unity. 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Proof of the great orthogonality theorem Prove that all representations can be unitary matrices Prove Schur’s lemma part 1 – any matrix which commutes with all matrices of an irreducible representation must be a constant matrix Prove Schur’s lemma part 2 Put all parts together 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Proof of the great orthogonality theorem Prove that all representations can be unitary matrices Prove Schur’s lemma part 1 – any matrix which commutes with all matrices of an irreducible representation must be a constant matrix Prove Schur’s lemma part 2 Put all parts together 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Prove that all representations can be unitary matrices 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Summation over all elements of group 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Note that all elements of the diagonal matrix d are real and positive. 1/18/2017 PHY 745 Spring 2017 -- Lecture 3

1/18/2017 PHY 745 Spring 2017 -- Lecture 3

Proved that all representations can be unitary matrices Consider our example: 1/18/2017 PHY 745 Spring 2017 -- Lecture 3