Global existence and non-existence of weak solutions for non-local stochastic semilinear reaction-diffusion equations driven by a fractional noise
Abstract
In the present paper, we study the existence and blow-up behavior to the following stochastic non-local reaction-diffusion equation: equation* \ aligned du(t,x)&=[(+γ) u(t,x)+∫Duq(t,y)dy -kup(t,x)+δ um(t,x)∫Dun(t,y)dy ]dt &+η u(t,x)dBH(t), u(t,x)&=0, \ \ t>0, \ \ x∈ ∂ D, u(0,x)&=f(x) ≥ 0, \ \ x∈ D, aligned . equation* where D⊂ Rd\ (d ≥ 1) is a bounded domain with smooth boundary ∂ D. Here, k>0, γ, δ, η ≥ 0 and p,q,n>1,\ m≥ 0 with m+n ≥ q≥ p. The initial data f is a non-negative bounded measurable function in class C2 which is not identically zero. Here, \ BH(t) \t ≥ 0 is a one-dimensional fractional Brownian motion with Hurst parameter 12 ≤ H<1 defined on a filtered probability space ( , F, (Ft)t ≥ 0, P ). First, we estimate a lower bound for the finite-time blow-up and by choosing a suitable initial data, we obtain the upper bound for the finite-time blow-up of the above equation. Next, we provide a sufficient condition for the global existence of a weak solution of the above equation. Further, we obtain the bounds for the probability of blow-up solution.
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