Scaling of local roughness distributions

Abstract

.Local roughness distributions (LRDs) are studied in the growth regimes of lattice models in the Kardar–Parisi–Zhang (KPZ) class in 1 + 1 and 2 + 1 dimensions and in a model of the Villain–Lai–Das Sarma (VLDS) growth class in 2 + 1 dimensions. The squared local roughness w2 is defined as the variance of the height inside a box of lateral size r, and the LRD is sampled as this box glides along a surface with size . The variation coefficient C and the skewness S of the distributions are functions of the scaled box size , where ξ is a correlation length. For , plateaus of C and S are observed, but with a small time dependence. For a quantitative characterization of the universal LRD, extrapolation of these values with power-law corrections in time is performed. The reliability of this procedure is confirmed in 1 + 1 dimensions by comparison of results of the restricted solid-on-solid model and theoretically predicted values of Edwards–Wilkinson interfaces. For , C and S vanish because the LRD converges to a Dirac delta function. This confirms the inadequacy of extrapolations of amplitude ratios to , as proposed in recent works. On the other hand, it highlights the advantage of scaling LRDs by the average instead of scaling by the variance due to the usually higher accuracy of C compared to S. The scaled LRD of the VLDS model is very close to the KPZ one due to the small difference between their variation coefficients, and the plateaus of C and S are very narrow due to the slow time increase of ξ. These results suggest that experimental LRDs obtained in short growth times and with limited resolution may be inconclusive to determine their universality classes if data accuracy is low and/or data extrapolation to the long time limit is not feasible.