Holomorphic functional calculus and vector-valued Littlewood-Paley-Stein theory for semigroups

Abstract

We study vector-valued Littlewood-Paley-Stein theory for semigroups of regular contractions \Tt\t>0 on Lp() for a fixed 1<p<∞. We prove that if a Banach space X is of martingale cotype q, then there is a constant C such that \|(∫0∞\|t∂∂ tPt (f)\|Xq\,dtt)1q\|Lp() C\, \|f\|Lp(; X)\,, ∀\, f∈ Lp(; X), where \Pt\t>0 is the Poisson semigroup subordinated to \Tt\t>0. Let LPc, q, p(X) be the least constant C, and let Mc, q(X) be the martingale cotype q constant of X. We show LPc,q, p(X) (p1q,\, p') Mc,q(X). Moreover, the order (p1q,\, p') is optimal as p1 and p∞. If X is of martingale type q, the reverse inequality holds. If additionally \Tt\t>0 is analytic on Lp(; X), the semigroup \Pt\t>0 in these results can be replaced by \Tt\t>0 itself. Our new approach is built on holomorphic functional calculus. Compared with all the previous, the new one is more powerful in several aspects: a) it permits us to go much further beyond the setting of symmetric submarkovian semigroups; b) it yields the optimal orders of growth on p for most of the relevant constants; c) it gives new insights into the scalar case for which our orders of the best constants in the classical Littlewood-Paley-Stein inequalities for symmetric submarkovian semigroups are better than the previous by Stein. In particular, we resolve a problem of Naor and Young on the optimal order of the best constant in the above inequality when X is of martingale cotype q and \Pt\t>0 is the classical Poisson and heat semigroups on Rd.