English

Quantum Eberlein compactifications and invariant means

Functional Analysis 2021-09-15 v2 Operator Algebras

Abstract

We propose a definition of a "CC^*-Eberlein" algebra, which is a weak form of a CC^*-bialgebra with a sort of "unitary generator". Our definition is motivated to ensure that commutative examples arise exactly from semigroups of contractions on a Hilbert space, as extensively studied recently by Spronk and Stokke. The terminology arises as the Eberlein algebra, the uniform closure of the Fourier-Stieltjes algebra B(G)B(G), has character space GEG^{\mathcal E}, which is the semigroup compactification given by considering all semigroups of contractions on a Hilbert space which contain a dense homomorphic image of GG. We carry out a similar construction for locally compact quantum groups, leading to a maximal CC^*-Eberlein compactification. We show that CC^*-Eberlein algebras always admit invariant means, and we apply this to prove various "splitting" results, showing how the CC^*-Eberlein compactification splits as the quantum Bohr compactification and elements which are annihilated by the mean. This holds for matrix coefficients, but for Kac algebras, we show it also holds at the algebra level, generalising (in a semigroup-free way) results of Godement.

Keywords

Cite

@article{arxiv.1406.1109,
  title  = {Quantum Eberlein compactifications and invariant means},
  author = {Biswarup Das and Matthew Daws},
  journal= {arXiv preprint arXiv:1406.1109},
  year   = {2021}
}

Comments

34 pages; minor corrections; to appear in Indiana University Mathematics Journal

R2 v1 2026-06-22T04:30:44.669Z