English

Non-autonomous stochastic evolution equations and applications to stochastic partial differential equations

Probability 2009-09-14 v4 Functional Analysis

Abstract

In this paper we study the following non-autonomous stochastic evolution equation on a UMD Banach space EE 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 (A(t))t[0,T](A(t))_{t\in [0,T]} are unbounded operators with domains (D(A(t)))t[0,T](D(A(t)))_{t\in [0,T]} which may be time dependent. We assume that (A(t))t[0,T](A(t))_{t\in [0,T]} satisfies the conditions of Acquistapace and Terreni. The functions FF and BB are nonlinear functions defined on certain interpolation spaces and u0Eu_0\in E is the initial value. WHW_H is a cylindrical Brownian motion on a separable Hilbert space HH. 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 UU of \eqref{eq:SEab}. For Hilbert spaces EE 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.

Keywords

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

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