The multilinear fractional sparse operator theory II: refining weighted estimates via multilinear fractional sparse forms
Abstract
This paper refines the main results from our previous study on sparse bounds of generalized commutators of multilinear fractional singular integral operators in CenSong2412. The key improvements are: 1. We replace pointwise domination with the (m+1)-linear fractional sparse form Aη,S,τ,r,s'b,k,t, advancing the vector-valued multilinear fractional sparse form domination principle, and relax conditions from multilinear weak type boundedness to multilinear locally weak type boundedness Wp, q(X). 2. We introduce a multilinear fractional r-type maximal operator Mη,r and develop a new class of weights A(p,q),(r, s)(X) to characterize it, establishing norm equivalence with the sparse forms. 3. This norm equivalence provides sharp quantitative weighted estimates for (m+1)-linear fractional sparse form, removing exponent parameter limitations and achieving sharp operator norm bounds. 4. We demonstrate applications in two ways: (1) Providing sharp or Bloom type estimates for generalized commutators of multilinear fractional Calder\'on--Zygmund operators and multilinear fractional rough singular integral operators. (2) Investigating sparse form type weighted Lebesgue Lp(ω) and weighted Sobolev Ws,p(ω) regularity estimates for solutions of fractional Laplacian equations with higher-order commutators.
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