Persistence of Randomly Coupled Fluctuating Interfaces
Abstract
We study the persistence properties in a simple model of two coupled interfaces characterized by heights h1 and h2 respectively, each growing over a d-dimensional substrate. The first interface evolves independently of the second and can correspond to any generic growing interface, e.g., of the Edwards-Wilkinson or of the Kardar-Parisi-Zhang variety. The evolution of h2, however, is coupled to h1 via a quenched random velocity field. In the limit d 0, our model reduces to the Matheron-de Marsily model in two dimensions. For d=1, our model describes a Rouse polymer chain in two dimensions advected by a transverse velocity field. We show analytically that after a long waiting time t0 ∞, the stochastic process h2, at a fixed point in space but as a function of time, becomes a fractional Brownian motion with a Hurst exponent, H2=1-β1/2, where β1 is the growth exponent characterizing the first interface. The associated persistence exponent is shown to be θs2=1-H2=β1/2. These analytical results are verified by numerical simulations.
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