SPDE Limit of Weakly Inhomogeneous ASEP

Abstract

We study ASEP in a spatially inhomogeneous environment on a torus T(N) = Z/NZ of N sites. A given inhomogeneity a(x) ∈ (0,∞) , x ∈ T , perturbs the overall asymmetric jumping rates r < ∈ (0,1) at bonds, so that particles jump from site x to x+1 with rate ra(x) and from x+1 to x with rate a(x) (subject to the exclusion rule in both cases). Under the limit N∞ , we suitably tune the asymmetry (-r) to zero like N-12 and the inhomogeneity a(x) to unity, so that the two compete on equal footing. At the level of the G\"artner (or microscopic Hopf--Cole) transform, we show convergence to a new SPDE -- the Stochastic Heat Equation with a mix of spatial and spacetime multiplicative noise. Equivalently, at the level of the height function we show convergence to the Kardar--Parisi--Zhang equation with a mix of spatial and spacetime additive noise. Our method applies to a general class of a(x) , which, in particular, includes i.i.d., long-range correlated, and periodic inhomogeneities. The key technical component of our analysis consists of a host of estimates on the kernel of the semigroup Q(t):=etH for a Hill-type operator H:= 12∂xx + A'(x) , and its discrete analog, where A (and its discrete analog) is a generic H\"older continuous function.