Martingale Suitable Weak Solutions of $3$-D Stochastic Navier-Stokes Equations with Vorticity Bounds

In this paper, we construct suitable weak martingale solutions for $3$-dimensional incompressible stochastic Navier-Stokes equations with linear multiplicative noise. In deterministic setting, as widely known, ``suitable weak solutions'' are Leray-Hopf weak solutions enjoying two different types of local energy inequalities. In stochastic setting, we are able to show corresponding stochastic versions of the two local energy inequalities, where a semi-martingale term occurs as the effect of the noise. Note that the exponential formulas, which are widely used to transform the stochastic PDEs system into a random one, DO NOT show up in our formulations of local energy inequality. This is different to \cite{FR02,Rom10} where the additive noise case is dealt. Also, a path-wise result in terms of ``a.e. super-martingale'' is derived from the stochastic local energy inequalities. Further more, if the initial vorticity is a finite Radon measure, we are able to bound the $L^1\big(\Omega;L^\infty([0,T];L^1)\big)$ norm of the vorticity and $L^{\frac{4}{3+\delta}}\big(\Omega\times[0,T]\times\mathbb T^3\big)$ norm of the gradient of the vorticity.