English

Weak $(1,1)$ estimates for multiple operator integrals and generalized absolute value functions

Functional Analysis 2020-10-21 v3 Operator Algebras

Abstract

Consider the generalized absolute value function defined by a(t)=ttn1,tR,nN1. a(t) = \vert t \vert t^{n-1}, \qquad t \in \mathbb{R}, n \in \mathbb{N}_{\geq 1}. Further, consider the nn-th order divided difference function a[n]:Rn+1Ca^{[n]}: \mathbb{R}^{n+1} \rightarrow \mathbb{C} and let 1<p1,,pn<1 < p_1, \ldots, p_n < \infty be such that l=1npl1=1\sum_{l=1}^n p_l^{-1} = 1. Let Spl\mathcal{S}_{p_l} denote the Schatten-von Neumann ideals and let S1,\mathcal{S}_{1,\infty} denote the weak trace class ideal. We show that for any (n+1)(n+1)-tuple A{\bf A} of bounded self-adjoint operators the multiple operator integral Ta[n]AT_{a^{[n]}}^{{\bf A}} maps Sp1××Spn\mathcal{S}_{p_1} \times \ldots \times \mathcal{S}_{p_n} to S1,\mathcal{S}_{1, \infty} boundedly with uniform bound in A{\bf A}. The same is true for the class of Cn+1C^{n+1}-functions that outside the interval [1,1][-1, 1] equal aa. In [CLPST16] it was proved that for a function ff in this class such boundedness of Tf[n]AT^{ {\bf A} }_{f^{[n]}} from Sp1××Spn\mathcal{S}_{p_1} \times \ldots \times \mathcal{S}_{p_n} to S1\mathcal{S}_{1} may fail, resolving a problem by V. Peller. This shows that the estimates in the current paper are optimal. The proof is based on a new reduction method for arbitrary multiple operator integrals of divided differences.

Keywords

Cite

@article{arxiv.2004.02145,
  title  = {Weak $(1,1)$ estimates for multiple operator integrals and generalized absolute value functions},
  author = {Martijn Caspers and Fedor Sukochev and Dmitriy Zanin},
  journal= {arXiv preprint arXiv:2004.02145},
  year   = {2020}
}

Comments

to appear in Israel Journal of Mathematics

R2 v1 2026-06-23T14:39:45.105Z