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Stochastic heat equation with white-noise drift. (English) Zbl 0970.60068
The authors study the existence and uniqueness of solutions for a one-dimensional anticipative stochastic evolution equation on the real line $u(t,x)=\int_{\mathbb R} p(0,t,y,x)u_0(y) dy + \int_{\mathbb R} \int_0^t p(s,t,y,x)F(s,y,u(s,y)) dW_{s,y}$ driven by a two-parameter Wiener process $$W_{t,x}$$ and based on a stochastic semigroup defined by the kernel $$p(s,t,y,x)$$. This kernel is supposed to be measurable w.r.t. the increments of the Wiener process on $$[s,t]\times\mathbb R$$. The results are based on $$L^p$$-estimates for the Skorokhod integral. As an application they establish the existence of a weak solution for the following heat equation on the real line subject to white noise drift, $\partial_t u(t,x)=\partial_x^2 u(t,x)+\dot{v}(t,x)\partial_x u(t,x)+F(t,x,u)\partial_t\partial_x W(t,x),$ where $$\dot{v}$$ is a white noise in time.

##### MSC:
 60H15 Stochastic partial differential equations (aspects of stochastic analysis) 35K05 Heat equation 60H25 Random operators and equations (aspects of stochastic analysis) 60H05 Stochastic integrals
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