Marina Ghisi, Massimo Gobbino, Alain Haraux
Published 2014-02-21Version 1
We consider an abstract first order evolution equation in a Hilbert space in which the linear part is represented by a self-adjoint nonnegative operator A with discrete spectrum, and the nonlinear term has order greater than one at the origin. We investigate the asymptotic behavior of solutions. We prove that two different regimes coexist. Close to the kernel of A the dynamic is governed by the nonlinear term, and solutions (when they decay to 0) decay as negative powers of t. Close to the range of A, the nonlinear term is negligible, and solutions behave as solutions of the linearized problem. This means that they decay exponentially to 0, with a rate and an asymptotic profile given by a simple mode, namely a one-frequency solution of the linearized equation. The abstract results apply to semilinear parabolic equations.
Capacitary estimates of solutions of semilinear parabolic equations
Semilinear elliptic problems in $\mathbb{R}^N$: the interplay between the potential and the nonlinear term
Large time behaviour for the heat equation on $\Z,$ moments and decay rates
![QR code for arXiv:1402.5355 [math.AP]](http://oss.arxitics.com/images/favicon.svg)