Regularization by Nonlinear Noise for PDEs: Well-posedness and Finite Time Extinction

TL;DR

This paper demonstrates that nonlinear noise can regularize certain PDEs, ensuring global solutions and preventing blow-up, with broad applications including Navier-Stokes and other stochastic PDEs.

Contribution

It establishes the global well-posedness of stochastic 3D Navier-Stokes equations and reveals that nonlinear noise can induce finite time extinction in explosive systems.

Findings

Proved global existence and uniqueness for stochastic 3D Navier-Stokes.

Discovered nonlinear noise can prevent blow-up and cause finite time extinction.

Applied results to various stochastic PDEs like p-Laplace and quasi-geostrophic equations.

Abstract

This work focuses on the regularization by nonlinear noise for a class of partial differential equations that may only have local solutions. In particular, we obtain the global existence, uniqueness and the Feller property for stochastic 3D Navier-Stokes equations, which provide positive answers to a longstanding open problem in this field. Moreover, we discover a new phenomenon that for a potentially explosive deterministic system, an appropriate intervention of nonlinear noise can not only prevent blow-up but also lead to the finite time extinction of the associated stochastic system. Our main results have broad applications, including stochastic $p$-Laplace equations with heat sources, stochastic surface growth models and stochastic quasi-geostrophic equations.