The Three-Dimensional Stochastic EMHD System: Local Well-Posedness and Maximal Pathwise Solutions

Abstract

We study the three-dimensional stochastic electron magnetohydrodynamics (EMHD) system with fractional dissipation on the torus, driven by Stratonovich transport noise acting through divergence-free first-order operators. The noise generates an It\o correction while preserving the transport structure of the Hall nonlinearity. Since the Hall term contains one more derivative, in the stochastic setting it must be controlled together with commutators arising from the transport operators. We develop a high-order Sobolev energy method based on Littlewood--Paley analysis and refined commutator estimates, which yields uniform bounds for Galerkin approximations in Hs with s > 52 together with suitable time regularity. Using stochastic compactness and identification of limits, we construct martingale solutions for initial data in L2(; Hs). Pathwise uniqueness follows from cancellations in the Hall term combined with a stochastic Gr\"onwall argument. An application of a Yamada--Watanabe type result then yields local pathwise well-posedness and the existence of maximal pathwise solutions.