Physics – Condensed Matter – Statistical Mechanics
Scientific paper
2007-03-19
Journal of Applied Physics, 101 (2007) 063507
Physics
Condensed Matter
Statistical Mechanics
24 pages, including 10 figures
Scientific paper
We study the local and global roughness scaling in growth models with grains at the film surfaces. The local roughness, measured as a function of window size r, shows a crossover at a characteristic length r_c, from a rapid increase with exponent \alpha_1 to a slower increase with exponent \alpha_2. The result \alpha_1\approx 1 is explained by the large height differences in the borders of the grains when compared to intragrain roughness, and must not be interpreted as a consequence of a diffusion dominated intragrain dynamics. This exponent shows a weak dependence on the shape and size distribution of the grains, and typically ranges from 0.85 for rounded grain surfaces to 1 for the sharpest ones. The scaling corrections of exactly solvable models suggest the possibility of slightly smaller values due to other smoothing effects of the surface images. The crossover length r_c provides a reasonable estimate of the average grain size in all model systems, including the cases of wide grain size distributions. In Kardar-Parisi-Zhang growth, very different values of \alpha_2 are obtained, ranging from 0.4 for the films with smoothest surfaces to values in the range 0.1\lesssim \alpha_2 \lesssim 0.2 for systems with large cliffs separating the grains. Possible applications to real systems which show this crossover with similar exponents are discussed.
Aarao Reis Fabio D. A.
Oliveira T. J.
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