Modeling of CO-deposition of indium and tin on silicon(100): A kinetic Monte Carlo study
Abstract
A growth model for co-deposition of Sn and In on Si(100) at room-temperature was simulated using Kinetic Monte Carlo methods to shed light on the chemical selectivity and lack of dimer ordering seen in [Jure et al., Appl. Surf. Sci. 162, 638 (2000)], a Scanning Tunneling Microscopy (STM) study. In this work, the experimental observation that the number of mixed InSn dimers is unaffected even when the relative flux rates are adjusted to favor In over Sn (by 100:1) a manifestation of some sort of chemical selectivity was investigated. Our simulations reveal that this phenomenon is ultimately related to the fact that the number of Sn-terminated chains is largely unaffected by the relative flux rate. Finally, we found that the attraction between metal dimers (whether of the same or different species) within a Si dimer row has only negligible effect on the apparent lack of dimer ordering seen in the STM study. Instead, dimer ordering is controlled by the detachment barriers in dimer-terminated islands. © 2011 World Scientific Publishing Company.
Source or Periodical Title
International Journal of Modern Physics B
ISSN
2179792
Page
1889-1898
Document Type
Article
Subject
Kinetic Monte Carlo simulations, nanowires, nucleation
Recommended Citation
Putungan, Darwin B.; Ramos, Henry J.; Chuang, Feng Chuan; and Albao, Marvin A., "Modeling of CO-deposition of indium and tin on silicon(100): A kinetic Monte Carlo study" (2021). Journal Article. 2390.
https://www.ukdr.uplb.edu.ph/journal-articles/2390