Strong solutions of a stochastic differential equation with irregular random drift

Abstract

We present a well-posedness result for strong solutions of one-dimensional stochastic differential equations (SDEs) of the form d X= u(ω,t,X)\, d t + 12 σ(ω,t,X)σ'(ω,t,X)\,d t + σ(ω,t,X) \, dW(t), where the drift coefficient u is random and irregular. The random and regular noise coefficient σ may vanish. The main contribution is a pathwise uniqueness result under the assumptions that u belongs to Lp(; L∞([0,T];H1(R))) for any finite p 1, E|u(t)-u(0)|H1(R)2 0 as t 0, and u satisfies the one-sided gradient bound ∂x u(ω,t,x) K(ω, t), where the process K(ω,t )>0 exhibits an exponential moment bound of the form E (p∫tT K(s)\,d s) t-2p for small times t, for some p1. This study is motivated by ongoing work on the well-posedness of the stochastic Hunter--Saxton equation, a stochastic perturbation of a nonlinear transport equation that arises in the modelling of the director field of a nematic liquid crystal. In this context, the one-sided bound acts as a selection principle for dissipative weak solutions of the stochastic partial differential equation (SPDE).

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