SDEs with supercritical distributional drifts
Abstract
Let d≥ 2. In this paper, we investigate the following stochastic differential equation (SDE) in Rd driven by Brownian motion d Xt=b(t,Xt) d t+2 d Wt, where b belongs to the space LTq Hpα with α ∈ [-1, 0] and p,q∈[2, ∞], which is a distribution-valued and divergence-free vector field. In the subcritical case dp+ 2q<1+α, we establish the existence and uniqueness of a weak solution to the integral equation: Xt=X0+n∞∫t0bn(s,Xs) d s+2 Wt. Here, bn:=b*φn represents the mollifying approximation, and the limit is taken in the L2-sense. In the critical and supercritical case 1+α≤ dp+ 2q<2+α, assuming the initial distribution has an L2-density, we show the existence of weak solutions and associated Markov processes. Moreover, under the additional assumption that b=b1+b2+ div a, where b1∈ L∞T B-1∞,2, b2∈ L2TL2, and a is a bounded antisymmetric matrix-valued function, we establish the convergence of mollifying approximation solutions without the need to subtract a subsequence. To illustrate our results, we provide examples of Gaussian random fields and singular interacting particle systems, including the two-dimensional vortex models.
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