Issue 2, 2019

Effective chemical potential for non-equilibrium systems and its application to molecular beam epitaxy of Bi2Se3

Abstract

First-principles studies often rely on the assumption of equilibrium, which can be a poor approximation, e.g., for growth. Here, an effective chemical potential ([small mu, Greek, macron]) method for non-equilibrium systems is developed. A salient feature of the theory is that it maintains the equilibrium limits as the correct limit. In application to molecular beam epitaxy, rate equations are solved for the concentrations of small clusters, which serve as feedstock for growth. We find that [small mu, Greek, macron] is determined by the most probable, rather than by the lowest-energy, cluster. In the case of Bi2Se3, [small mu, Greek, macron] is found to be highly supersaturated, leading to a high nucleus concentration in agreement with experiment.

Graphical abstract: Effective chemical potential for non-equilibrium systems and its application to molecular beam epitaxy of Bi2Se3

Supplementary files

Article information

Article type
Communication
Submitted
07 Aug 2018
Accepted
29 Sep 2018
First published
10 Oct 2018
This article is Open Access
Creative Commons BY-NC license

Nanoscale Adv., 2019,1, 470-475

Effective chemical potential for non-equilibrium systems and its application to molecular beam epitaxy of Bi2Se3

N. Wang, D. West, W. Duan and S. B. Zhang, Nanoscale Adv., 2019, 1, 470 DOI: 10.1039/C8NA00136G

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