Non-autonomous stochastic evolution equations and applications to stochastic partial differential equations
Abstract
In this paper we study the following non-autonomous stochastic evolution equation on a UMD Banach space with type 2, {equation}\label{eq:SEab}\tag{SE} {{aligned} dU(t) & = (A(t)U(t) + F(t,U(t))) dt + B(t,U(t)) dW_H(t), \quad t\in [0,T], U(0) & = u_0. {aligned}. {equation} Here are unbounded operators with domains which may be time dependent. We assume that satisfies the conditions of Acquistapace and Terreni. The functions and are nonlinear functions defined on certain interpolation spaces and is the initial value. is a cylindrical Brownian motion on a separable Hilbert space . Under Lipschitz and linear growth conditions we show that there exists a unique mild solution of \eqref{eq:SEab}. Under assumptions on the interpolation spaces we extend the factorization method of Da Prato, Kwapie\'n, and Zabczyk, to obtain space-time regularity results for the solution of \eqref{eq:SEab}. For Hilbert spaces we obtain a maximal regularity result. The results improve several previous results from the literature. The theory is applied to a second order stochastic partial differential equation which has been studied by Sanz-Sol\'e and Vuillermot. This leads to several improvements of their result.
Cite
@article{arxiv.0806.4439,
title = {Non-autonomous stochastic evolution equations and applications to stochastic partial differential equations},
author = {Mark Veraar},
journal= {arXiv preprint arXiv:0806.4439},
year = {2009}
}
Comments
Accepted for publication in Journal of Evolution Equations