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A MOLECULAR DYNAMICS SIMULATION OF DIAMOND/SILICON(001) INTERFACE
Author(s) -
Dai Yong-Bing,
Shen He-Sheng,
Zhiming Zhang,
Xiancong He,
Xiaojun Hu,
Fanghong Sun,
Haiwei Xin
Publication year - 2001
Publication title -
wuli xuebao
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.199
H-Index - 47
ISSN - 1000-3290
DOI - 10.7498/aps.50.244
Subject(s) - molecular dynamics , diamond , interface (matter) , silicon , computer science , materials science , dynamics (music) , chemical physics , optoelectronics , parallel computing , computational chemistry , composite material , physics , chemistry , bubble , maximum bubble pressure method , acoustics
The structure of diamond/silicon interface, which was formed by the contact and the subsequent relaxation of the unreconstructed (001) surfaces of diamond film and silicon substrate, has been investigated by molecular dynamics simulation.The interaction among atoms of the silicon/carbon binary system was described by Tersoff many-body empirical potential. Before relaxation, the ratios of silicon atoms to carbon atoms along [110] and [110] directions are both 3∶2 and the ratio of the total number of interfacial silicon atoms to that of carbon is 9∶4. After relaxation, the matching of diamond and silicon lattices has been changed: along[110] direction, a 3∶2 coincidence relation is roughly remained, but along [110] direction, a 1∶1 coincidence relation is approximately adopted. Accordingly, the ratio of the total number of interfacial silicon atoms to that of carbon is near 3∶2. The migration of partial silicon atoms, which were originally in the second layer, upward to the interface is responsible for such changes. The silicon lattice near the interface shows the tendency of disordering along [001] direction. The strong bonding between interfacial silicon and carbon atoms was found and Si-C bonds with an average length of 0.189 nm were formed. This study has confirmed that the main feature of lattice matching is the meeting of silicon atoms at and near the interface to the arrangement of interfacial carbon atoms.

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