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An Invariant Set Bifurcation Theory for Nonautonomous Nonlinear Evolution Equations

Dynamical Systems 2020-01-22 v1

Abstract

In this paper we establish an invariant set bifurcation theory for the nonautonomous dynamical system (\va\lam,\0)X,\cH(\va_\lam,\0)_{X,\cH} generated by the evolution equation \be\label{e0}u_t+Au=\lam u+p(t,u),\hs p\in \cH=\cH[f(\.,u)]\ee on a Hilbert space XX, where AA is a sectorial operator, \lam\lam is the bifurcation parameter, f(,˙u):R\raXf(\.,u):\R\ra X is translation compact, f(t,0)0f(t,0)\equiv0 and \cH[f]\cH[f] is the hull of f(,˙u)f(\.,u). Denote by \va\lam:=\va\lam(t,p)u\va_\lam:=\va_\lam(t,p)u the cocycle semiflow generated by the equation. Under some other assumptions on ff, we show that as the parameter \lam\lam crosses an eigenvalue \lam0R\lam_0\in\R of AA, the system bifurcates from 00 to a nonautonomous invariant set B\lam()˙B_\lam(\.) on one-sided neighborhood of \lam0\lam_0. Moreover, \lim_{\lam\ra\lam_0}H_{X^\a}\(B_\lam(p),0\)=0,\hs p\in P, where HX\a(,˙)˙H_{X^\a}(\.,\.) denotes the Hausdorff semidistance in X\aX^\a (here XαX^\alpha (\a0\a\geq0) defined below is the fractional power spaces associated with AA). Our result is based on the pullback attractor bifurcation on the local central invariant manifolds \cMloc\lam()˙\cM^\lam_{loc}(\.).

Keywords

Cite

@article{arxiv.2001.07318,
  title  = {An Invariant Set Bifurcation Theory for Nonautonomous Nonlinear Evolution Equations},
  author = {Xuewei Ju and Ailing Qi},
  journal= {arXiv preprint arXiv:2001.07318},
  year   = {2020}
}
R2 v1 2026-06-23T13:16:03.479Z