Best constants in the vector-valued Littlewood-Paley-Stein theory

Abstract

Let L be a sectorial operator of type α (0 ≤ α < π/2) on L2(Rd) with the kernels of \e-tL\t>0 satisfying certain size and regularity conditions. Define Sq,L(f)(x) = (∫0∞∫|y-x| < t \|tLe-tL (f)(y) \|Xq \, d y d ttd+1 )1q, Gq,L(f)=( ∫0∞ \|tLe-tL (f)(y) \|Xq \, d tt)1q. We show that for any Banach space X, 1 ≤ p < ∞ and 1 < q < ∞ and f∈ Cc( Rd) X, there hold align* p-1q\| Sq,(f) \|p d, γ, β \| Sq,L(f) \|p d, γ, β p1q\| Sq,(f) \|p, align* align* p-1q\| Sq,L(f) \|p d, γ, β \| Gq,L(f) \|p d, γ, β p1q\| Sq,L(f) \|p, align* where is the standard Laplacian; moreover all the orders appeared above are optimal as p→1. This, combined with the existing results in [29, 33], allows us to resolve partially Problem 1.8, Problem A.1 and Conjecture A.4 regarding the optimal Lusin type constant and the characterization of martingale type in a recent remarkable work due to Xu [48]. Several difficulties originate from the arbitrariness of X, which excludes the use of vector-valued Calder\'on-Zygmund theory. To surmount the obstacles, we introduce the novel vector-valued Hardy and BMO spaces associated with sectorial operators; in addition to Mei's duality techniques and Wilson's intrinsic square functions developed in this setting, the key new input is the vector-valued tent space theory and its unexpected amalgamation with these `old' techniques.