Large fluctuations of a Kardar-Parisi-Zhang interface on a half-line

Abstract

Consider a stochastic interface h(x,t), described by the 1+1 Kardar-Parisi-Zhang (KPZ) equation on the half-line x≥ 0. The interface is initially flat, h(x,t=0)=0, and driven by a Neumann boundary condition ∂x h(x=0,t)=A and by the noise. We study the short-time probability distribution P(H,A,t) of the one-point height H=h(x=0,t). Using the optimal fluctuation method, we show that - P(H,A,t) scales as t-1/2 s (H,A t1/2). For small and moderate |A| this more general scaling reduces to the familiar simple scaling - P(H,A,t) t-1/2 s(H), where s is independent of A and time and equal to one half of the corresponding large-deviation function for the full-line problem. For large |A| we uncover two asymptotic regimes. At very short time the simple scaling is restored, whereas at intermediate times the scaling remains more general and A-dependent. The distribution tails, however, always exhibit the simple scaling in the leading order.