An Invariant Set Bifurcation Theory for Nonautonomous Nonlinear Evolution Equations

Abstract

In this paper we establish an invariant set bifurcation theory for the nonautonomous dynamical system (,\0)X, generated by the evolution equation e0ut+Au= u+p(t,u), p∈ =[f(\.,u)] on a Hilbert space X, where A is a sectorial operator, is the bifurcation parameter, f(\.,u): X is translation compact, f(t,0)0 and [f] is the hull of f(\.,u). Denote by :=(t,p)u the cocycle semiflow generated by the equation. Under some other assumptions on f, we show that as the parameter crosses an eigenvalue 0∈ of A, the system bifurcates from 0 to a nonautonomous invariant set B(\.) on one-sided neighborhood of 0. Moreover, _0HX\(B(p),0\)=0, p∈ P, where HX(\.,\.) denotes the Hausdorff semidistance in X (here Xα (≥0) defined below is the fractional power spaces associated with A). Our result is based on the pullback attractor bifurcation on the local central invariant manifolds loc(\.).