Stochastic Generalized Porous Media Equations Over $$\sigma $$ -finite Measure Spaces with Non-continuous Diffusivity Function

IF 1 3区数学 Q1 MATHEMATICS

Potential Analysis Pub Date : 2024-03-04 DOI:10.1007/s11118-024-10127-7

Michael Röckner, Weina Wu, Yingchao Xie

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引用次数: 0

Abstract

In this paper, we prove that stochastic porous media equations over $\sigma $-finite measure spaces $(E,\mathcal {B},\mu )$, driven by time-dependent multiplicative noise, with the Laplacian replaced by a self-adjoint transient Dirichlet operator L and the diffusivity function given by a maximal monotone multi-valued function $\Psi $ of polynomial growth, have a unique solution. This generalizes previous results in that we work on general measurable state spaces, allow non-continuous monotone functions $\Psi $, for which, no further assumptions (as e.g. coercivity) are needed, but only that their multi-valued extensions are maximal monotone and of at most polynomial growth. Furthermore, an $L^p(\mu )$-Itô formula in expectation is proved, which is not only crucial for the proof of our main result, but also of independent interest. The result in particular applies to fast diffusion stochastic porous media equations (in particular self-organized criticality models) and cases where E is a manifold or a fractal, and to non-local operators L, as e.g. $L=-f(-\Delta )$, where f is a Bernstein function.

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具有非连续扩散函数的 $$\sigma $$ - 无限测度空间上的随机广义多孔介质方程

在本文中，我们证明了在（（E,\mathcal {B},\mu ））无限度量空间上的随机多孔介质方程，在时间相关乘法噪声的驱动下，拉普拉奇算子由自相关瞬态迪里夏特算子L代替，扩散函数由多项式增长的最大单调多值函数$\Psi $给出，具有唯一解。这概括了之前的结果，即我们在一般的可测状态空间上工作，允许非连续的单调函数（$\Psi $），对于这些函数，不需要进一步的假设（如矫顽力），只需要它们的多值扩展是最大单调的，并且最多具有多项式增长。此外，还证明了期望中的$L^p(\mu )$-Itô公式，这不仅对我们主要结果的证明至关重要，而且具有独立的意义。该结果尤其适用于快速扩散随机多孔介质方程（特别是自组织临界模型）、E为流形或分形的情况，以及非局部算子L，例如$L=-f(-\Delta )$，其中f为伯恩斯坦函数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Potential Analysis 数学-数学

CiteScore

2.20

自引率

9.10%

发文量

审稿时长

>12 weeks

期刊介绍： The journal publishes original papers dealing with potential theory and its applications, probability theory, geometry and functional analysis and in particular estimations of the solutions of elliptic and parabolic equations; analysis of semi-groups, resolvent kernels, harmonic spaces and Dirichlet forms; Markov processes, Markov kernels, stochastic differential equations, diffusion processes and Levy processes; analysis of diffusions, heat kernels and resolvent kernels on fractals; infinite dimensional analysis, Gaussian analysis, analysis of infinite particle systems, of interacting particle systems, of Gibbs measures, of path and loop spaces; connections with global geometry, linear and non-linear analysis on Riemannian manifolds, Lie groups, graphs, and other geometric structures; non-linear or semilinear generalizations of elliptic or parabolic equations and operators; harmonic analysis, ergodic theory, dynamical systems; boundary value problems, Martin boundaries, Poisson boundaries, etc.