Boundedness of Riesz transforms for elliptic operators on abstract Wiener spaces

Abstract

Let (E,H,mu) be an abstract Wiener space and let DV := VD, where D denotes the Malliavin derivative and V is a closed and densely defined operator from H into another Hilbert space G. Given a bounded operator B on G, coercive on the closure of the range of V, we consider the realisation of the operator DV* B DV in Lp(E,mu) for 1<p<∞. Our main result states that the following assertions are equivalent: (1) dom((sqrt(DV* B DV)) = dom(DV) and Meyer's inequalities hold for DV* B DV; (2) DV DV* B admits a bounded H-infinity calculus on the closure of the range of DV; (3) dom(sqrt(V*BV)) = dom(V) and Meyer's inequalities hold for V*BV; (4) VV*B admits a bounded H-infinity calculus on the closure of the range of V. Moreover, if these conditions are satisfied, then dom(L) = dom(DV2) dom(DA). The equivalence of (1)-(4) is a non-symmetric generalisation of the classical Meyer inequalities (which correspond to the case G=H, V=I, B=I). A one-sided version of the main result, giving Lp-boundedness of the associated Riesz transforms in terms of a square function estimate, is also obtained. As an application let -A generate an analytic C0-contraction semigroup on a Hilbert space H and let -L be the Lp-realisation of the generator of its second quantisation. Our results imply that two-sided bounds for the Riesz transform of L are equivalent with the Kato square root property for A.