Kinetics of step bunching during growth: A minimal model
arXiv:cond-mat/0409324 · doi:10.1103/PhysRevE.71.041605
Abstract
We study a minimal stochastic model of step bunching during growth on a one-dimensional vicinal surface. The formation of bunches is controlled by the preferential attachment of atoms to descending steps (inverse Ehrlich-Schwoebel effect) and the ratio $d$ of the attachment rate to the terrace diffusion coefficient. For generic parameters ($d > 0$) the model exhibits a very slow crossover to a nontrivial asymptotic coarsening exponent $β\simeq 0.38$. In the limit of infinitely fast terrace diffusion ($d=0$) linear coarsening ($β$ = 1) is observed instead. The different coarsening behaviors are related to the fact that bunches attain a finite speed in the limit of large size when $d=0$, whereas the speed vanishes with increasing size when $d > 0$. For $d=0$ an analytic description of the speed and profile of stationary bunches is developed.
8 pages, 10 figures