Asymptotically autonomous robustness in Probability of non-autonomous random attractors for stochastic convective Brinkman-Forchheimer equations on R3
Abstract
This article is concerned with the asymptotically autonomous robustness (almost surely and in probability) of non-autonomous random attractors for two stochastic versions of 3D convective Brinkman-Forchheimer (CBF) equations defined on the whole space R3: ∂v∂ t-μ v+(v·∇)v +αv+ β|v|r-1v+∇ p=f(t)+``stochastic terms", ∇·v=0, with initial and boundary vanishing conditions, where μ,α,β >0, r≥1 and f(·) is a given time-dependent external force field. By the asymptotically autonomous robustness of a non-autonomous random attractor A=\ A(τ,ω): τ∈R, ω∈\ we mean its time-section A(τ,ω) is robust to a time-independent random set as time τ tends to negative infinity according to the Hausdorff semi-distance of the underlying space. Our goal is to study this topic, almost surely and in probability, for the non-autonomous 3D CBF equations when the stochastic term is a linear multiplicative or additive noise, and the time-dependent forcing converges towards a time-independent function. Our main results contain two cases: i) r∈(3,∞) with any β,μ>0; ii) r=3 with 2βμ≥1. The main procedure to achieve our goal is how to justify that the usual pullback asymptotic compactness of the solution operators is uniform on some uniformly tempered universes over an infinite time-interval (-∞,τ]. This can be done by a method based on Kuratowski's measure of noncompactness.
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