cohomology of compact connected Lie groups


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This entry aims to describe some properties of the cohomology (http://planetmath.org/DeRhamCohomology) of compact (http://planetmath.org/Compact) connected (http://planetmath.org/ConnectedSpace) Lie groupsMathworldPlanetmath. It turns out that this type of Lie groups admit a somewhat simplified cohomology theory, compared with singular cohomology or de Rham cohomologyMathworldPlanetmath. This simplified theory then allows one to observe some of the imposed on the structure of the cohomology groupsPlanetmathPlanetmath of compact connected Lie groups.

The construction and results presented in the entry on invariant differential forms are assumed and will be the of what we are about to describe.

1 Cohomology of invariant forms

Let G be a compact connected Lie group. Given a differential manifold M and smooth action of G in M, let ΩGk(M) denote the space of the k-invariant differential forms (http://planetmath.org/InvariantDifferentialForm) in M. It is known (see this entry (http://planetmath.org/InvariantDifferentialForm)) that ΩG*(M) forms a chain complexMathworldPlanetmath and the cohomology groups of this complex are isomorphic to the cohomology groups of M, i.e.

Hk(ΩG(M))Hk(M;)

We now regard the manifold M as a compact connected Lie group G. There are several smooth actions on G that are worth to be considered, such as:

  • The action of G on itself by left multiplication.

  • The action of G on itself by right multiplication.

  • The action of G on itself by conjugation.

  • The action of G×G on G given by (g,h)k:=gkh-1

Thus, by the previous remark, the cohomology of a compact connected Lie group G restricts to the cohomology of left invariant forms, right invariant forms, adjoint invariant forms or bi-invariant forms (http://planetmath.org/InvariantDifferentialForm). Moreover, the cohomology of G is the cohomology of differential formsMathworldPlanetmath invariant under any smooth action of any compact connect Lie group on G .

1.1 Left invariant forms

Since left invariant forms are uniquely determined by their values in TeG, the tangent space (http://planetmath.org/TangentSpace) at the identity, they allow a simpler characterization of the cohomology of compact connected Lie groups.

Proposition - Let G be a compact connected Lie group and TeG* the chain complex of alternating forms on TeG with coboundary operator d given by

dω(X0,,Xk)=i<j(-1)i+jω([Xi,Xj],X0,,Xi^,,Xj^,,Xk)

Then, the cohomology groups of Hk(G,) are isomorphic to the cohomology groups Hk(TeG*) of the complex TeG*.

1.2 Bi-invariant forms

Two sided invariance is just the same as left invariance adjoint invariance. Hence, every bi-invariant form can be seen as an alternating form on TeG wich is also adjoint invariant. Thus, just like the previous proposition, the cohomology groups of G are just the cohomology groups of the complex TeGad* of adjoint invariant alternating forms on TeG, with coboundary operator

dω(X0,,Xk)=i<j(-1)i+jω([Xi,Xj],X0,,Xi^,,Xj^,,Xk)

This can be further improved. The following important theorem will be the key to more specific results.

Theorem 1 - Let G be a compact connected Lie group. Let ω be a multilinearMathworldPlanetmath k-form on Te. Then ω is adjoint invariant if and only if the following equality holds:

i=1kω(X1,,Xi-1,[Y,Xi],Xi+1,,Xk)=0  for allY,X1,,XkTeG

Proposition - Every adjoint invariant alternating form on TeG is closed (http://planetmath.org/ClosedDifferentialForm).

Proof: Let αi,i=0, αi,j=(-1)j if i<j and αi,j=(-1)j+1 if i>j. Then

dω(X0,,Xk) = 12ij(-1)iαi,jω([Xi,Xj],X0,,Xi^,,Xj^,,Xk)
= 12i(-1)ijαi,jω([Xi,Xj],X0,,Xi^,,Xj^,,Xk)
= 0

where the sum is zero by Theorem 1.

Corollary 1 - Let G be a compact connected Lie group. The cohomology groups Hk(G;) are isomorphic to the vector spaceMathworldPlanetmath of adjoint invariant alternating k-forms on TeG.

2 Relations between cohomology groups

Let G be a compact connected Lie group. In the proofs of the following results we are always using the fact stated in Corollary 1, that Hk(G;) is exactly the space of adjoint invariant alternating k-forms on TeG. Let [TeG,TeG] denote the subspacePlanetmathPlanetmath (http://planetmath.org/VectorSubspace) of TeG generated by elements of the form [X,Y], with X,YTeG.

Proposition - [TeG,TeG]=TeGH1(G;)=0

Proof: It follows easily form the fact that adjoint invariant alternating 1-forms on TeG are precisely those who satisfy ω([X,Y])=0 for all X,YTeG (Theorem 1).

Corollary - H1(G;)=0H2(G;)=0

Proof: Let ω be an adjoint invariant 2-form on TeG. We have that

0=dω(X,Y,Z) = -ω([X,Y],Z)+ω([X,Z],Y)-ω([Y,Z],X)
= -ω([X,Y],Z)-(ω([Z,X],Y)+ω(X,[Z,Y]))
= -ω([X,Y],Z)

where the last step comes from Theorem 1. Now, as [TeG,TeG]=TeG by the previous Proposition, ω=0.

Let Sym2 be the space of adjoint invariant symmetric bilinear formsMathworldPlanetmath on TeG and TeGadk the space of adjoint invariant alternating k-forms on TeG.

Theorem 2 - Suppose H1(G;)=0. The functionMathworldPlanetmath Φ:Sym2TeG3 defined by

Φ(η)(X,Y,Z):=η([X,Y],Z),X,Y,ZTeG

is well defined and bijective.

One can always assure the existence of nonzero adjoint invariant symmetric bilinear forms on TeG. This can be achieved by taking an inner product , on TeG and defining, for X,YTeG,

η(X,Y):=1μ(G)G(Cg)*X,(Cg)*Y𝑑μ(g)

where μ is the Haar measure of G and Cg is the function of conjugation by gG. Hence we can conclude that

Corollary - Suppose G is nontrivial. Then H1(G;)=0H3(G;)0

Title cohomology of compact connected Lie groups
Canonical name CohomologyOfCompactConnectedLieGroups
Date of creation 2013-03-22 17:49:47
Last modified on 2013-03-22 17:49:47
Owner asteroid (17536)
Last modified by asteroid (17536)
Numerical id 10
Author asteroid (17536)
Entry type Feature
Classification msc 57T10
Classification msc 58A12
Classification msc 55N99
Classification msc 22E15
Related topic InvariantDifferentialForm