Bilinear decompositions and commutators of singular integral operators

Abstract

Let b be a BMO-function. It is well-known that the linear commutator [b, T] of a Calder\'on-Zygmund operator T does not, in general, map continuously H1( Rn) into L1( Rn). However, P\'erez showed that if H1( Rn) is replaced by a suitable atomic subspace H1b( Rn) then the commutator is continuous from H1b( Rn) into L1( Rn). In this paper, we find the largest subspace H1b( Rn) such that all commutators of Calder\'on-Zygmund operators are continuous from H1b( Rn) into L1( Rn). Some equivalent characterizations of H1b( Rn) are also given. We also study the commutators [b,T] for T in a class K of sublinear operators containing almost all important operators in harmonic analysis. When T is linear, we prove that there exists a bilinear operators R= RT mapping continuously H1( Rn)× BMO( Rn) into L1( Rn) such that for all (f,b)∈ H1( Rn)× BMO( Rn), we have abstract 1 [b,T](f)= R(f,b) + T( S(f,b)), where S is a bounded bilinear operator from H1( Rn)× BMO( Rn) into L1( Rn) which does not depend on T. In the particular case of T a Calder\'on-Zygmund operator satisfying T1=T*1=0 and b in BMO log( Rn)-- the generalized type space that has been introduced by Nakai and Yabuta to characterize multipliers of (n) --we prove that the commutator [b,T] maps continuously H1b( Rn) into h1( Rn). Also, if b is in BMO( Rn) and T*1 = T*b = 0, then the commutator [b, T] maps continuously H1b ( Rn) into H1( Rn). When T is sublinear, we prove that there exists a bounded subbilinear operator R= RT: H1( Rn)× BMO( Rn) L1( Rn) such that for all (f,b)∈ H1( Rn)× BMO( Rn), we have abstract 2 |T( S(f,b))|- R(f,b)≤ |[b,T](f)|≤ R(f,b) + |T( S(f,b))|. The bilinear decomposition (abstract 1) and the subbilinear decomposition (abstract 2) allow us to give a general overview of all known weak and strong L1-estimates.