Exact height distribution in one-dimensional Edwards-Wilkinson interface with diffusing diffusivity
Abstract
We study the height distribution of a one-dimensional Edwards-Wilkinson interface in the presence of a stochastic diffusivity D(t)=B2(t), where B(t) represents a one-dimensional Brownian motion at time t. The height distribution at a fixed point is space is computed analytically. The typical height h(x,t) at a given point in space is found to scale as t3/4 and the distribution G(H) of the scaled height H=h/t3/4 is symmetric but with a nontrivial shape: while it approaches a nonzero constant quadratically as H 0, it has a non-Gaussian tail that decays exponentially for large H. We show that this exponential tail is rather robust and holds for a whole family of linear interface models parametrized by a dynamical exponent z>1, with z=2 corresponding to the Edwards-Wilkinson model.
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