In this paper we compare the elastic energies obtained by tight-binding molecular dynamics simulations for several strained structures of β-FeSi2, corresponding to the most frequent epitaxial relationships `on' and `in' silicon. Our results confirm that, for coherent interfaces, the very common β-FeSi2(101) or (110)∥Si(111) orientation generates a very large contribution to the elastic energy, due to the large misfit. Therefore, we suggest that the frequent nucleation of such epitaxial relationships in precipitates is provided by the correspondence of the two-dimensional crystal structure for the Si sites between Si(111) and β-FeSi2(101) or (110). We show it to be maintained even after misfit relaxation in the silicon matrix, as simulated by a large-scale molecular dynamics run.
Gemelli, M., Miglio, L. (2000). Interface structure at the large misfit, still common epitaxy β-FeSi2(101) or (110)∥Si(111). Intervento presentato a: Spring Meeting of the European-Materials-Research-Society - MAY 29-JUN 02 2000, Strasburgo, France [10.1016/S0040-6090(00)01532-7].
Interface structure at the large misfit, still common epitaxy β-FeSi2(101) or (110)∥Si(111)
Miglio, L
2000
Abstract
In this paper we compare the elastic energies obtained by tight-binding molecular dynamics simulations for several strained structures of β-FeSi2, corresponding to the most frequent epitaxial relationships `on' and `in' silicon. Our results confirm that, for coherent interfaces, the very common β-FeSi2(101) or (110)∥Si(111) orientation generates a very large contribution to the elastic energy, due to the large misfit. Therefore, we suggest that the frequent nucleation of such epitaxial relationships in precipitates is provided by the correspondence of the two-dimensional crystal structure for the Si sites between Si(111) and β-FeSi2(101) or (110). We show it to be maintained even after misfit relaxation in the silicon matrix, as simulated by a large-scale molecular dynamics run.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.