English

Exponential decay estimates for Singular Integral operators

Classical Analysis and ODEs 2013-04-16 v2

Abstract

The following subexponential estimate for commutators is proved |[|\{x\in Q: |[b,T]f(x)|>tM^2f(x)\}|\leq c\,e^{-\sqrt{\alpha\, t\|b\|_{BMO}}}\, |Q|, \qquad t>0.\] where cc and α\alpha are absolute constants, TT is a Calder\'on--Zygmund operator, MM is the Hardy Littlewood maximal function and ff is any function supported on the cube QQ. It is also obtained |\{x\in Q: |f(x)-m_f(Q)|>tM_{1/4;Q}^#(f)(x) \}|\le c\, e^{-\alpha\,t}|Q|,\qquad t>0, where mf(Q)m_f(Q) is the median value of ff on the cube QQ and M_{1/4;Q}^# is Str\"omberg's local sharp maximal function. As a consequence it is derived Karagulyan's estimate {xQ:Tf(x)>tMf(x)}cectQt>0,|\{x\in Q: |Tf(x)|> tMf(x)\}|\le c\, e^{-c\, t}\,|Q|\qquad t>0, improving Buckley's theorem. A completely different approach is used based on a combination of "Lerner's formula" with some special weighted estimates of Coifman-Fefferman obtained via Rubio de Francia's algorithm. The method is flexible enough to derive similar estimates for other operators such as multilinear Calder\'on--Zygmund operators, dyadic and continuous square functions and vector valued extensions of both maximal functions and Calder\'on--Zygmund operators. On each case, MM will be replaced by a suitable maximal operator.

Keywords

Cite

@article{arxiv.1204.1666,
  title  = {Exponential decay estimates for Singular Integral operators},
  author = {Carmen Ortiz-Caraballo and Carlos Pérez and Ezequiel Rela},
  journal= {arXiv preprint arXiv:1204.1666},
  year   = {2013}
}

Comments

To appear in Mathematische Annalen

R2 v1 2026-06-21T20:46:08.503Z