A proof of Onsager's conjecture for the stochastic 3D Euler equations

Abstract

This paper investigates the stochastic 3D Euler equations on a periodic domain T3, driven by a GG*-Wiener process B of trace class: align* d u+div(u u)\,d t+∇ p\,dt=dB, div u=0. align* First, for any <1/3, we construct infinitely many global-in-time probabilistically strong and analytically weak solutions u∈ C([0,∞),C(T3,R3)). These solutions dissipate the energy pathwisely up to a stopping time t, which can be chosen arbitrarily large with high probability, i.e. it holds almost surely align* \|u(tt)\|L22< \|u(st)\|L22 +2 ∫sttt u(r), d B(r) +Tr(GG*) (tt-st), align* for any 0≤ s < t<∞. We also provide a brief proof of energy conservation for >1/3 based on CET94, thereby confirming the Onsager theorem for the stochastic 3D Euler equations. Second, let 0<<β<1/3, we construct infinitely many global-in-time probabilistically strong and analytically weak solutions in C([0,∞),C(T3,R3)) for arbitrary divergence-free initial data in Cβ(T3,R3). Our construction relies on the convex integration method developed in the deterministic setting by Ise18, adapting it to the stochastic context by introducing a novel energy inequality into the convex integration scheme and combining stochastic analysis arguments with a Wong--Zakai type estimate.