Spatial Decay of Rotating Waves in Reaction Diffusion Systems

Abstract

In this paper we study nonlinear problems for Ornstein-Uhlenbeck operators align* A v(x) + Sx,∇ v(x) + f(v(x)) = 0,\,x∈Rd,\,d≥slant 2, align* where the matrix A∈RN,N is diagonalizable and has eigenvalues with positive real part, the map f:RN→RN is sufficiently smooth and the matrix S∈Rd,d in the unbounded drift term is skew-symmetric. Nonlinear problems of this form appear as stationary equations for rotating waves in time-dependent reaction diffusion systems. We prove under appropriate conditions that every bounded classical solution v of the nonlinear problem, which falls below a certain threshold at infinity, already decays exponentially in space, in the sense that v belongs to an exponentially weighted Sobolev space W1,pθ(Rd,RN). Several extensions of this basic result are presented: to complex-valued systems, to exponential decay in higher order Sobolev spaces and to pointwise estimates. We also prove that every bounded classical solution v of the eigenvalue problem align* A v(x) + Sx,∇ v(x) + Df(v(x))v(x) = λ v(x),\,x∈Rd,\,d≥slant 2, align* decays exponentially in space, provided Re\,λ lies to the right of the essential spectrum. As an application we analyze spinning soliton solutions which occur in the Ginzburg-Landau equation. Our results form the basis for investigating nonlinear stability of rotating waves in higher space dimensions and truncations to bounded domains.