English

Local atomic decompositions for multidimensional Hardy spaces

Functional Analysis 2020-05-19 v3

Abstract

We consider a nonnegative self-adjoint operator LL on L2(X)L^2(X), where XRdX\subseteq \mathbb{R}^d. Under certain assumptions, we prove atomic characterizations of the Hardy space H1(L)=\l{fL1(X) :  supt>0 exp(tL)f  L1(X)< }.H^1(L) = \l \{f\in L^1(X) \ : \ \ {\|}\sup_{t>0} \ |\exp(-tL)f \ | \ {\|}_{L^1(X)}<\infty\ \}. We state simple conditions, such that H1(L)H^1(L) is characterized by atoms being either the classical atoms on XRdX\subseteq \mathbb{R}^d or local atoms of the form Q1χQ|Q|^{-1}\chi_Q, where QXQ\subseteq X is a cube (or cuboid). One of our main motivation is to study multidimensional operators related to orthogonal expansions. We prove that if two operators L1,L2L_1, L_2 satisfy the assumptions of our theorem, then the sum L1+L2L_1 + L_2 also does. As a consequence, we give atomic characterizations for multidimensional Bessel, Laguerre, and Schr\"odinger operators. As a by-product, under the same assumptions, we characterize H1(L)H^1(L) also by the maximal operator related to the subordinate semigroup exp(tLν)\exp(-tL^\nu), where ν(0,1)\nu\in(0,1).

Keywords

Cite

@article{arxiv.1810.06937,
  title  = {Local atomic decompositions for multidimensional Hardy spaces},
  author = {Edyta Kania and Paweł Plewa and Marcin Preisner},
  journal= {arXiv preprint arXiv:1810.06937},
  year   = {2020}
}
R2 v1 2026-06-23T04:41:31.304Z