Local and Global Dynamic Bifurcations of Nonlinear Evolution Equations

Abstract

We present new local and global dynamic bifurcation results for nonlinear evolution equations of the form ut+A u=fλ(u) on a Banach space X, where A is a sectorial operator, and λ∈ R is the bifurcation parameter. Suppose the equation has a trivial solution branch \(0,λ):\,\,λ∈ R\. Denote λ the local semiflow generated by the initial value problem of the equation. It is shown that if the crossing number n at a bifurcation value λ=λ0 is nonzero and moreover, S0=\0\ is an isolated invariant set of λ0, then either there is a one-sided neighborhood I1 of λ0 such that λ bifurcates a topological sphere Sn-1 for each λ∈ I1\λ0\, or there is a two-sided neighborhood I2 of λ0 such that the system λ bifurcates from the trivial solution an isolated nonempty compact invariant set Kλ with 0∈ Kλ for each λ∈ I2\λ0\. We also prove that the bifurcating invariant set has nontrivial Conley index. Building upon this fact we establish a global dynamical bifurcation theorem. Roughly speaking, we prove that for any given neighborhood of the bifurcation point (0,λ0), the connected bifurcation branch from (0,λ0) either meets the boundary ∂ of , or meets another bifurcation point (0,λ1). This result extends the well-known Rabinowitz's Global Bifurcation Theorem to the setting of dynamic bifurcations of evolution equations without requiring the crossing number to be odd. As an illustration example, we consider the well-known Cahn-Hilliard equation. Some global features on dynamical bifurcations of the equation are discussed.