Maximal Lp-regularity for stochastic evolution equations

Abstract

We prove maximal Lp-regularity for the stochastic evolution equation \[\aligned dU(t) + A U(t)\, dt& = F(t,U(t))\,dt + B(t,U(t))\,dWH(t), t∈ [0,T], U(0) & = u0, aligned.\] under the assumption that A is a sectorial operator with a bounded H∞-calculus of angle less than 12π on a space Lq(O,μ). The driving process WH is a cylindrical Brownian motion in an abstract Hilbert space H. For p∈ (2,∞) and q∈ [2,∞) and initial conditions u0 in the real interpolation space we prove existence of unique strong solution with trajectories in \[Lp(0,T;(A)) C([0,T];),\] provided the non-linearities F:[0,T]× (A) Lq(O,μ) and B:[0,T]× (A) (H,(A12)) are of linear growth and Lipschitz continuous in their second variables with small enough Lipschitz constants. Extensions to the case where A is an adapted operator-valued process are considered as well. Various applications to stochastic partial differential equations are worked out in detail. These include higher-order and time-dependent parabolic equations and the Navier-Stokes equation on a smooth bounded domain ⊂eq d with d 2. For the latter, the existence of a unique strong local solution with values in (H1,q())d is shown.