English

Stochastic Kimura Equations

Probability 2024-02-06 v2

Abstract

In this work we study the one-dimensional stochastic Kimura equation tu(z,t)=zz2u(z,t)+u(z,t)W˙(z,t)\partial_{t}u\left(z,t\right)=z\partial_{z}^{2}u\left(z,t\right)+u\left(z,t\right)\dot{W}\left(z,t\right) for z,t>0z,t>0 equipped with a Dirichlet boundary condition at 00, with W˙\dot{W} being a Gaussian space-time noise. This equation can be seen as a degenerate analog of the parabolic Anderson model. We combine the Wiener chaos theory from Malliavin calculus, the Duhamel perturbation technique from PDEs, and the kernel analysis of (deterministic) degenerate diffusion equations to develop a solution theory for the stochastic Kimura equation. We establish results on existence, uniqueness, moments, and continuity for the solution u(z,t)u\left(z,t\right). In particular, we investigate how the stochastic potential and the degeneracy in the diffusion operator jointly affect the properties of u(z,t)u\left(z,t\right) near the boundary. We also derive explicit estimates on the comparison under the L2L^{2}- norm between u(z,t)u\left(z,t\right) and its deterministic counterpart for (z,t)\left(z,t\right) within a proper range.

Keywords

Cite

@article{arxiv.2401.16570,
  title  = {Stochastic Kimura Equations},
  author = {Roland Riachi and Linan Chen},
  journal= {arXiv preprint arXiv:2401.16570},
  year   = {2024}
}

Comments

45 pages

R2 v1 2026-06-28T14:30:52.312Z