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Structure, energy, and electronic properties of the {Sigma} = 13 {l_brace}510{r_brace} tilt grain boundary structure in Si

Name: Structure, energy, and electronic properties of the {Sigma} = 13 {l_brace}510{r_brace} tilt grain boundary structure in Si
Keywords: Binding Energy, Silicon, Crystallography, Electronic Structure, Grain Boundaries, 36 Materials Science

descriptionPublicationkeyboard_double_arrow_right Article 31 Dec 1997 United States English Publisher:Ames Laboratory

Authors: Morris, J. R.; Lu, Z. Y.; Ring, D. M.; Xiang, J. B.; Ho, K. M.; Wang, C. Z.; Fu, C. L.;

Structure, energy, and electronic properties of the {Sigma} = 13 {l_brace}510{r_brace} tilt grain boundary structure in Si

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Abstract

The authors have examined a variety of structures for the {l_brace}510{r_brace} symmetric tilt boundary in Si, using first-principles calculations. These calculations show that the observed structure in Si is the lowest energy structure. This structure is more complicated than what is necessary to preserve four-fold coordination. They compare the results to classical and tight-binding models, in order to test these empirical approaches.

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United States

Related Organizations

University of North Texas
United States
University of North Texas
United States

Keywords

Binding Energy, Silicon, Crystallography, Electronic Structure, Grain Boundaries, 36 Materials Science

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