English

Gelfand-Type problems in Random Walk Spaces

Analysis of PDEs 2024-10-30 v1

Abstract

This paper deals with Gelfand-type problems \begin{equation}\label{Gelfand10} \qquad\qquad\left\{\begin{array}{ll} - \Delta_m u = \lambda f(u), \quad&\hbox{in} \ \Omega, \ \lambda >0, \\[10pt] u =0, \quad&\hbox{on} \ \partial_m\Omega, \end{array} \right. \end{equation} in the framework of Random Walk Spaces, which includes as particular cases: Gelfand-type problems posed on locally finite weighted connected graphs and Gelfand-type problems driven by convolution integrable kernels. Under the same assumption on the nonlinearity ff as in the local case, we show there exists an extremal parameter λ(0,)\lambda^* \in (0, \infty) such that, for 0λ<λ0 \leq \lambda < \lambda^*, problem \eqref{Gelfand10} admits a minimal bounded solution uλu_\lambda and there are not solution for λ>λ\lambda > \lambda^*. Moreover, assuming ff is convex, we show that Problem \eqref{Gelfand10} admits a minimal bounded solution for λ=λ\lambda = \lambda^*. We also show that uλu_\lambda are stable, and, for ff strictly convex, we show that they are the unique stable solutions. We give simple examples that illustrate the many situations that can occur when solving Gelfand-type problems on weighted graphs.

Keywords

Cite

@article{arxiv.2410.21927,
  title  = {Gelfand-Type problems in Random Walk Spaces},
  author = {J. M. Mazon and A. Molino and J. Toledo},
  journal= {arXiv preprint arXiv:2410.21927},
  year   = {2024}
}
R2 v1 2026-06-28T19:39:27.609Z