English

Noncommutative Cotlar identities for groups acting on tree-like structures

Functional Analysis 2024-12-24 v2 Analysis of PDEs Operator Algebras

Abstract

Let TmT_m be a noncommutative Fourier multiplier. In recent work, Mei and Ricard introduced a noncommutative analogue of Cotlar's identity in order to prove that certain multipliers are bounded on the non-commutative LpL_p-spaces of a free group. Here, we study Cotlar type identities in full generality, giving a closed characterization for them in terms of mm: (m(gh)m(g))(m(g1)m(h))=0,  gG{e},hG. \big( m(g h) - m(g) \big) \, \big( m(g^{-1}) - m(h) \big) = 0, \; \forall g \in \mathrm{G} \setminus \{e\}, h \in \mathrm{G}. We manage to prove, using a geometric argument, that if XX is a tree -- or more generally an R\mathbb{R}-tree -- on which G\mathrm{G} acts and mm lifts to a function m~:XC\widetilde{m}: X \to \mathbb{C} that is constant on the connected subsets of X{x0}X \setminus \{x_0\}, then mm satisfies Cotlar's identity and thus TmT_m is bounded in LpL_p for 1<p<1 < p < \infty. This result establishes a new connection between groups actions on R\mathbb{R}-trees and Fourier multipliers. We show that mm is trivial when the action has global fixed points. This machinery allows us to simultaneously generalize the free group transforms of Mei and Ricard and the theory of Hilbert transforms in left-orderable groups, which follows from Arveson's subdiagonal algebras. Using Bass-Serre theory, we construct new examples of Fourier multipliers in groups. Those include new families like Baumslag-Solitar groups. We also show that a natural Hilbert transform in PSL2(C)\mathrm{PSL}_2(\mathbb{C}) satisfies Cotlar's identity when restricted to the Bianchi group PSL2(Z[1])\mathrm{PSL}_2(\mathbb{Z}[\sqrt{-1}]).

Keywords

Cite

@article{arxiv.2209.05298,
  title  = {Noncommutative Cotlar identities for groups acting on tree-like structures},
  author = {Adrian Gonzalez-Perez and Javier Parcet and Runlian Xia},
  journal= {arXiv preprint arXiv:2209.05298},
  year   = {2024}
}

Comments

Minor mistakes corrected. The introduction and Sections 1 and 4 are slightly improved. A Remark on Schur multipliers has been added to Section 1. In Section 4, Theorem 4.2 has been added

R2 v1 2026-06-28T01:08:10.163Z