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Small fluctuations in epitaxial growth via conservative noise

Published

Author(s)

Paul N. Patrone, Rongrong Wang, Dionisios Margetis

Abstract

We study the combined effect of growth (material deposition from above) and nearest-neighbor entropic and force-dipole interactions in a stochastically perturbed system of N line defects (steps) on a vicinal crystal surface in 1+1 dimensions. First, we formulate a general model of conservative white noise, and we derive simplified formulas for the terrace width distribution (TWD) and pair correlations, particularly the covariance matrix of terrace widths, in the limit N → ∞ for small step fluctuations. Second, we apply our formalism to two specific noise models which stem, respectively, from: (i) the fluctuation-dissipation theorem for diffusion of adsorbed atoms; and (ii) the phenomenological consideration of deposition-flux- induced asymmetric attachment and detachment of atoms at step edges. We discuss implications of our analysis, particularly the narrowing of the TWD with the deposition flux, connection of noise structure to terrace width correlations, behavior of these correlations in the macroscopic limit, and comparison of our perturbation results to a known mean field approach.
Citation
Journal of Physics A-Mathematical and General
Volume
44
Issue
31

Keywords

Epitaxial growth, force dipole interaction, covariance, terrace width distribution, conservative noise, Burton-Cabrera-Frank (BCF) model

Citation

Patrone, P. , Wang, R. and Margetis, D. (2011), Small fluctuations in epitaxial growth via conservative noise, Journal of Physics A-Mathematical and General, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=908523 (Accessed March 28, 2024)
Created July 7, 2011, Updated February 19, 2017