Exponentially weighted resolvent estimates for complex Ornstein-Uhlenbeck systems

Abstract

In this paper we study differential operators of the form align* [L∞ v ](x) = A v(x) + Sx,∇ v(x) - Bv(x), \,x ∈ Rd, \,d ≥slant 2, align* for matrices A,B∈CN,N, where the eigenvalues of A have positive real parts. The sum A v(x) + Sx, ∇ v(x) is known as the Ornstein-Uhlenbeck operator with an unbounded drift term defined by a skew-symmetric matrix S∈Rd,d. Differential operators such as L∞ arise as linearizations at rotating waves in time-dependent reaction diffusion systems. The results of this paper serve as foundation for proving exponential decay of such waves. Under the assumption that A and B can be diagonalized simultaneously we construct a heat kernel matrix H(x,,t) of L∞ that solves the evolution equation vt=L∞v. In the following we study the Ornstein-Uhlenbeck semigroup align* [ T(t)v](x) = ∫Rd H(x,,t) v() d,\,x ∈ Rd,\, t>0, align* in exponentially weighted function spaces. This is used to derive resolvent estimates for L∞ in exponentially weighted Lp-spaces Lpθ (Rd,CN), 1≤slant p<∞, as well as in exponentially weighted Cb-spaces Cb,θ(Rd,CN).