We analyze the limiting behavior of the densitiesρA(t) andρB(t), and the random spatial structureξ(r) = (ξA(t).,ξB(t)), for the diffusion-controlled chemical reaction A+B→inert. For equal initial densitiesρB(0) = ρb(0) there is a change in behavior fromd⩽ 4, where ρA(t) =ρB(t) ≈C/td/4, tod ⩾ 4, where ρA(t) =ρb(t) ≈C/t ast → ∞; the termC depends on the initial densities and changes withd. There is a corresponding change in the spatial structure. Ind < 4, the particle types separate with only one type present locally, and ξ, after suitable rescaling, tends to a random Gaussian process. Ind >4, both particle types are, after large times, present locally in concentrations not depending on type or location. Ind=4, both particle types are present locally, but with random concentrations, and the process tends to a limit.
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