Global existence for perturbations of the 2D stochastic Navier-Stokes equations with space-time white noise

Abstract

We prove global in time well-posedness for perturbations of the 2D stochastic Navier-Stokes equations equation* ∂t u + u · ∇ u = u - ∇ p + ζ + \;, u (0, ·) = u0(·) \;, div (u) = 0 \;, equation* driven by additive space-time white noise , with perturbation ζ in the H\"older-Besov space C-2 + 3 , periodic boundary conditions and initial condition u0 ∈ C-1 + for any >0 . The proof relies on an energy estimate which in turn builds on a dynamic high-low frequency decomposition and tools from paracontrolled calculus. Our argument uses that the solution to the linear equation is a -correlated field, yielding a double exponential growth bound on the solution. Notably, our method does not rely on any explicit knowledge of the invariant measure to the SPDE, hence the perturbation ζ is not restricted to the Cameron-Martin space of the noise, and the initial condition may be anticipative. Finally, we introduce a notion of weak solution that leads to well-posedness for all initial data u0 in L2 , the critical space of initial conditions.