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6. One-Dimensional Continuous Groups

6. One-Dimensional Continuous Groups. 6.1 The Rotation Group SO(2) 6.2 The Generator of SO(2) 6.3 Irreducible Representations of SO(2) 6.4 Invariant Integration Measure, Orthonormality and Completeness Relations 6.5 Multi-Valued Representations

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6. One-Dimensional Continuous Groups

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  1. 6. One-Dimensional Continuous Groups 6.1 The Rotation Group SO(2) 6.2 The Generator of SO(2) 6.3 Irreducible Representations of SO(2) 6.4 Invariant Integration Measure, Orthonormality and Completeness Relations 6.5 Multi-Valued Representations 6.6 Continuous Translational Group in One Dimension 6.7 Conjugate Basis Vectors

  2. Introduction • Lie Group, rough definition: Infinite group that can be parametrized smoothly & analytically. • Exact definition: A differentiable manifold that is also a group. • Linear Lie groups = Classical Lie groups = Matrix groups E.g. O(n), SO(n), U(n), SU(n), E(n), SL(n), L, P, … • Generators, Lie algebra • Invariant measure • Global structure / Topology

  3. 6.1. The Rotation Group SO(2) 2-D Euclidean space Rotations about origin O by angle  :

  4. by  Rotation is length preserving:  i.e., R() is special orthogonal. If O is orthogonal, 

  5. Theorem 6.1: There is a 1–1 correspondence between rotations in En & SO(n) matrices. Proof: see Problem 6.1 Geometrically: and Theorem 6.2: 2-D Rotational Group R2 = SO(2) is an Abelian group under matrix multiplication with identity element and inverse Proof: Straightforward. SO(2) is a Lie group of 1 (continuous) parameter  SO(2) group manifold

  6. 6.2. The Generator of SO(2) Lie group: elements connected to E can be acquired by a few generators. For SO(2), there is only 1 generator J defined by J is a 22 matrix R() is continuous function of    with Theorem 6.3: Generator J of SO(2)

  7. Comment: • Structure of a Lie group ( the part that's connected to E ) is determined by a set of generators. • These generators are determined by the local structure near E. • Properties of the portions of the group not connected to E are determined by global topological properties.  Pauli matrix J is traceless, Hermitian, & idempotent ( J2 = E )

  8. 6.3. IRs of SO(2) Let U() be the realization of R() on V.  U() unitary  J Hermitian SO(2) Abelian  All of its IRs are 1-D The basis |   of a minimal invariant subspace under SO(2) can be chosen as so that   IR Um : m = 0: Identity representation

  9. m = 1: SO(2) mapped clockwise onto unit circle in C plane m = 1: … counterclockwise … m = n: SO(2) mapped n times around unit circle in C plane Theorem 6.4: IRs of SO(2) Single-valued IRs of SO(2) are given by Only m = 1 are faithful Representation is reducible has eigenvalues 1 with eigenvectors  Problem 6.2

  10. 6.4. Invariant Integration Measure, Orthonormality & Completeness Relations Finite group g  Continuous group  dg Issue 1: Different parametrizations Let G = { g() } & define where  = ( 1, …n ) & f is any complex-valued function of g. Changing parametrization to  = (), we have, Remedy: Introduce weight : so that 

  11. ( Notation changed ! ) Issue 2: Rearrangement Theorem Since R.T. is satisfied by setting M = G if dg is (left) invariant, i.e., Let  

  12. From one can determine the (vector) function  :  where e(0) is arbitrary Theorem 6.5: SO(2) Proof:  Setting e(0) = 1 completes proof.

  13. Theorem 6.6: Orthonormality & Completeness Relations for SO(2) Orthonormality Completeness Proof: These are just the Fourier theorem since • Comments: • These relations are generalizations of the finite group results with g   dg • Cf. results for Td ( roles of continuous & discrete labels reversed )

  14. 6.5. Multi-Valued Representations Consider representation 2-valued representation m-valued representations : ( if n,m has no common factor ) • Comments: • Multi-connected manifold  multi-valued IRs: • For SO(2): group manifold = circle  Multi-connected because paths of different winding numbers cannot be continuously deformed into each other. • Only single & double valued reps have physical correspondence in 3-D systems ( anyons can exist in 2-D systems ).

  15. 6.6. Continuous Translational Group in 1-D R() ~ translation on unit circle by arc length   Similarity between reps of R(2) & Td Let the translation by distance x be denoted by T(x) Given a state | x0 localized at x0, is localized at x0+x     is a 1-parameter Abelian Lie group = Continuous Translational Group in 1-D

  16. Generator P:   For a unitary representation T(x)  Up(x), P is Hermitian with real eigenvalue p. Basis of Up(x) is the eigenvector | p  of P: • Comments: • IRs of SO(2), Td & T1 are all exponentials: e–i m , e–i k n b & e–i p x, resp. • Cause: same group multiplication rules. • Group parameters are • continuous & bounded for SO(2) = { R() } • discrete & unbounded for Td = { T(n) } • continuous & unbounded for T1 = { T(x) }

  17. Invariant measure for T1:  Orthonormality Completeness C = (2)–1 is determined by comparison with the Fourier theorem.

  18. 6.7. Conjugate Basis Vectors • Reminder: 2 kind of basis vectors for Td. • | x  localized state • | E k  extended normal mode • For SO(2): • |   = localized state at ( r=const,  ) • | m  = eigenstate of J & R() Setting gives  m  transfer matrix elements  m |   = representation function e–i m 

  19. 2 ways to expand an arbitrary state |   :

  20.   J is Hermitian:  in the x-representation  J = angular momentum component  plane of rotation

  21. For T1: • | x  = localized state at x • | p  = eigenstate of P & T(x) T is unitary  p | 0  set to 1

  22. 2 ways to expand an arbitrary state |   : P+ = P : on V = span{ | x  }  P = linear momentum

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