English

Lp Solutions for Stochastic Evolution Equation with Nonlinear Potential

Probability 2022-02-11 v7

Abstract

This article considers the stochastic partial differential equation {ut=12uxx+uγξu(0,.)=u0 \left\{ \begin{array}{l} u_t = \frac{1}{2} u_{xx} + u^\gamma \xi u(0,.) = u_0 \end{array}\right. \noindent where ξ\xi is a space / time white noise Gaussian random field, γ>1\gamma > 1 and u0u_0 is a non-negative initial condition independent of ξ\xi satisfying u00,limn+E[(S1u0(x)ndx)2]=E[(S1u0(x)dx)2]<+. u_0 \geq 0, \qquad \lim_{n \rightarrow +\infty} \mathbb{E} \left [ \left (\int_{\mathbb{S}^1} u_0 (x)\wedge n dx \right)^2 \right ] = \mathbb{E} \left [ \left (\int_{\mathbb{S}^1} u_0 (x) dx \right)^2 \right ]< +\infty. \noindent The {\em space} variable is xS1=[0,1]x \in \mathbb{S}^1 = [0,1] with the identification 0=10 = 1. The definition of the stochastic term, taken in the sense of Walsh, will be made clear in the article. The result is that there exists a unique non-negative solution uu such that for all α[0,1)\alpha \in [0,1), E[(0S1u(t,x)2γdxdt)α/2]C(α)<+.\mathbb{E} \left [ \left( \int_0^\infty \int_{\mathbb{S}^1} u(t,x)^{2\gamma} dx dt \right)^{\alpha / 2 } \right ] \leq C( \alpha) < + \infty. \noindent where the constant C(α)C(\alpha) arises in the Burkholder-Davis-Gundy inequality. The solution is also shown to satisfy E[0T(S1u(t,x)pdx)α/pdt]<+T<+,p<+,α(0,12). \mathbb{E} \left [ \int_0^T \left(\int_{\mathbb{S}^1} u (t,x)^p dx \right)^{\alpha / p} dt \right ] < +\infty \qquad \forall T < +\infty, \qquad p < +\infty, \qquad \alpha \in \left (0, \frac{1}{2} \right ).

Keywords

Cite

@article{arxiv.1406.0970,
  title  = {Lp Solutions for Stochastic Evolution Equation with Nonlinear Potential},
  author = {John M. Noble},
  journal= {arXiv preprint arXiv:1406.0970},
  year   = {2022}
}

Comments

proof involved change of probability space - it was not proved that the limiting object satisfied the equation

R2 v1 2026-06-22T04:30:14.385Z