Group algebra of a locally compact group
In mathematics, the group algebra is any of various constructions to assign to a locally compact group an operator algebra (or more generally a Banach algebra), such that representations of the algebra are related to representations of the group. As such, they are similar to the group ring associated to a discrete group.
Group algebras of topological groups: Cc(G)
For the purposes of functional analysis, and in particular of harmonic analysis, one wishes to carry over the group ring construction to topological groups G. In case G is a locally compact Hausdorff group, G carries an essentially unique left-invariant countably additive Borel measure μ called a Haar measure. Using the Haar measure, one can define a convolution operation on the space Cc(G) of complex-valued continuous functions on G with compact support; Cc(G) can then be given any of various norms and the completion will be a group algebra.
To define the convolution operation, let f and g be two functions in Cc(G). For t in G, define
The fact that f * g is continuous is immediate from the dominated convergence theorem. Also
where the dot stands for the product in G. Cc(G) also has a natural involution defined by:
where Δ is the modular function on G. With this involution, it is a *-algebra.
Theorem. With the norm:
Cc(G) becomes an involutive normed algebra with an approximate identity.
The approximate identity can be indexed on a neighborhood basis of the identity consisting of compact sets. Indeed, if V is a compact neighborhood of the identity, let fV be a non-negative continuous function supported in V such that
Then {fV}V is an approximate identity. A group algebra has an identity, as opposed to just an approximate identity, if and only if the topology on the group is the discrete topology.
Note that for discrete groups, Cc(G) is the same thing as the complex group ring C[G].
The importance of the group algebra is that it captures the unitary representation theory of G as shown in the following
Theorem. Let G be a locally compact group. If U is a strongly continuous unitary representation of G on a Hilbert space H, then
is a non-degenerate bounded *-representation of the normed algebra Cc(G). The map
is a bijection between the set of strongly continuous unitary representations of G and non-degenerate bounded *-representations of Cc(G). This bijection respects unitary equivalence and strong containment. In particular, πU is irreducible if and only if U is irreducible.
Non-degeneracy of a representation π of Cc(G) on a Hilbert space Hπ means that
is dense in Hπ.
The convolution algebra L1(G)
It is a standard theorem of measure theory that the completion of Cc(G) in the L1(G) norm is isomorphic to the space L1(G) of equivalence classes of functions which are integrable with respect to the Haar measure, where, as usual, two functions are regarded as equivalent if and only if they differ only on a set of Haar measure zero.
Theorem. L1(G) is a Banach *-algebra with the convolution product and involution defined above and with the L1 norm. L1(G) also has a bounded approximate identity.
The group C*-algebra C*(G)
Let C[G] be the group ring of a discrete group G.
For a locally compact group G, the group C*-algebra C*(G) of G is defined to be the C*-enveloping algebra of L1(G), i.e. the completion of Cc(G) with respect to the largest C*-norm:
where π ranges over all non-degenerate *-representations of Cc(G) on Hilbert spaces. When G is discrete, it follows from the triangle inequality that, for any such π, one has:
hence the norm is well-defined.
It follows from the definition that C*(G) has the following universal property: any *-homomorphism from C[G] to some B(H) (the C*-algebra of bounded operators on some Hilbert space H) factors through the inclusion map:
The reduced group C*-algebra Cr*(G)
The reduced group C*-algebra Cr*(G) is the completion of Cc(G) with respect to the norm
where
is the L2 norm. Since the completion of Cc(G) with regard to the L2 norm is a Hilbert space, the Cr* norm is the norm of the bounded operator acting on L2(G) by convolution with f and thus a C*-norm.
Equivalently, Cr*(G) is the C*-algebra generated by the image of the left regular representation on ℓ2(G).
In general, Cr*(G) is a quotient of C*(G). The reduced group C*-algebra is isomorphic to the non-reduced group C*-algebra defined above if and only if G is amenable.
von Neumann algebras associated to groups
The group von Neumann algebra W*(G) of G is the enveloping von Neumann algebra of C*(G).
For a discrete group G, we can consider the Hilbert space ℓ2(G) for which G is an orthonormal basis. Since G operates on ℓ2(G) by permuting the basis vectors, we can identify the complex group ring C[G] with a subalgebra of the algebra of bounded operators on ℓ2(G). The weak closure of this subalgebra, NG, is a von Neumann algebra.
The center of NG can be described in terms of those elements of G whose conjugacy class is finite. In particular, if the identity element of G is the only group element with that property (that is, G has the infinite conjugacy class property), the center of NG consists only of complex multiples of the identity.
NG is isomorphic to the hyperfinite type II1 factor if and only if G is countable, amenable, and has the infinite conjugacy class property.
Stereotype group algebras
In stereotype theory there is a series of natural group algebras that includes the following four main examples.
- On each locally compact group one can consider the algebra of all continuous functions with the topology of uniform convergence on compact sets . The stereotype dual space , which consists of Radon measures with compact support on a locally compact group , is a stereotype algebra with respect to the operation of convolution:[1]
- The algebra is called the stereotype group algebra of measures on the locally compact group .[2]
- On each real Lie group one can consider the algebra of all smooth functions with the topology of uniform convergence with all derivatives on compact sets . The stereotype dual space , which consists of distributions with compact support on , is a stereotype algebra with respect to the operation of convolution of distributions. The algebra is called the stereotype group algebra of distributions on the real Lie group .
- On each Stein group[3] one can consider the algebra of all holomorphic functions with the topology of uniform convergence on compact sets . The stereotype dual space , which consists of holomorphic fuhctionals on , is a stereotype algebra with respect to the operation of convolution of functionals. The algebra is called the stereotype group algebra of analytic functionals on the Stein group .
- On each affine algebraic group one can consider the algebra of all polynomials (or regular functions) with the strongest locally convex topology. The stereotype dual space , which consists of currents on , is a stereotype algebra with respect to the operation of convolution of currents. The algebra is called the stereotype group algebra of currents on the affine algebraic group .
A map of a group into an associative unital algebra is called a representation of in , if it is a group homomorphism into the group of invertible elements of , i.e. if it satisfies the following identities:
The representation , , , is called the representation as delta-functionals.
The representations , , , are defined similarly.
The following two results distinguish the stereotype group algebras among the other models of group algebras in analysis.
- Theorem (universal property).[4] For any stereotype algebra the formula
- establishes a one-to-one correspondence between
- the continuous representations of a locally compact group in the stereotype algebra and the morphisms of stereotype algebras ,
- the smooth[5] representations of a real Lie group in the stereotype algebra and the morphisms of stereotype algebras ,
- the holomorphic[6] representations of a Stein group in the stereotype algebra and the morphisms of stereotype algebras ,
- the polynomial (regular)[7] representations of an affine algebraic group in the stereotype algebra and the morphisms of stereotype algebras .
- Theorem.[8] The group algebras , , , are Hopf algebras in the monoidal category (Ste,,) of stereotype spaces.
See also
Notes
- ^ Akbarov 2003, p. 272.
- ^ If is an infinite locally compact group then the algebra of measures on is not a Fréchet algebra. In the case when is compact, is a Smith space. If is -compact, then is a Brauner space.
- ^ A Stein group is a complex Lie group which is a Stein manifold.
- ^ Akbarov 2003, p. 275.
- ^ A map of a smooth manifold into a stereotype space is said to be smooth if for each functional the composition is a smooth function on , and the map is continuous.
- ^ A map of a Stein manifold into a stereotype space is said to be holomorphic if for each functional the composition is a holomorphic function on , and the map is continuous.
- ^ A map of an affine algebraic variety over into a stereotype space is said to be polynomial (or regular) if for each functional the composition is a polynomial on , and the map is continuous.
- ^ Akbarov 2009, p. 507.
References
- J, Dixmier, C* algebras, ISBN 0-7204-0762-1
- A. A. Kirillov, Elements of the theory of representations, ISBN 0-387-07476-7
- L. H. Loomis, "Abstract Harmonic Analysis", ASIN B0007FUU30
- A.I. Shtern (2001) [1994], "Group algebra of a locally compact group", Encyclopedia of Mathematics, EMS Press This article incorporates material from Group $C^*$-algebra on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.
- Akbarov, S.S. (2003). "Pontryagin duality in the theory of topological vector spaces and in topological algebra". Journal of Mathematical Sciences. 113 (2): 179–349. doi:10.1023/A:1020929201133.
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(help) - Akbarov, S.S. (2009). "Holomorphic functions of exponential type and duality for Stein groups with algebraic connected component of identity". Journal of Mathematical Sciences. 162 (4): 459–586. arXiv:0806.3205. doi:10.1007/s10958-009-9646-1.
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