Fluctuation-Dominated Phase Ordering Driven by Stochastically Evolving Surfaces

We study a new kind of phase ordering phenomenon in coarse-grained depth (CD) models of the hill-valley profile of fluctuating surfaces with zero overall tilt, and for hard-core particles sliding on such surfaces under gravity. For Edwards-Wilkinson (EW) and Kardar-Parisi-Zhang (KPZ) surfaces, our analytic and numerical results show that CD models exhibit coarsening to an ordered steady state in which the order parameter has a broad distribution even in the thermodynamic limit. Moreover, the distribution of particle cluster sizes decays as a power-law (with an exponent $\theta$), and the scaled 2-point spatial correlation function has a cusp (with an exponent $\alpha = 1/2$) at small values of the argument. The latter feature indicates a deviation from the Porod law. For linear CD models with dynamical exponent $z$, we show that $\alpha = (z - 1)/2$ for $z < 3$, while $\alpha = 1$ for $z > 3$, and there are logarithmic corrections for $z = 3$. This implies $\alpha = 1/2$ for the EW surface and 1 for the Golubovic-Bruinsma-Das Sarma-Tamborenea (GBDT) surface. Within the independent interval approximation we show that $\alpha + \theta = 2$. The scaled density-density correlation function of the sliding particle model shows a cusp with exponent $\alpha \simeq 0.5$, and 0.25 for the EW and KPZ surfaces. The particles on the GBDT surface show conventional coarsening (Porod) behavior with $\alpha \simeq 1$.