Theory of electronic properties of amorphous silicon-carbon alloys: effects of short-range disorder
Journal
Solid State Communications
Date Issued
September 1993
Author(s)
DOI
10.1016/0038-1098(93)90428-P
Abstract
Homopolar (like-atom) bonding and thresfold carbon coordination are found to drastically affect the electronic properties of amorphous silicon-carbon alloys. First-principles pseudopotential calculations based on amorphous geometries obtained from Monte Carlo empirical simulations show that incorporating C in Si-rich samples, in tetrahedral arrangements with heteropolar bonds only, increases the energy gap. This tendency is drastically reversed in C-rich samples because of graphitelike geometries. Like-atom bonds, in samples of all compositions, reduce the gap as well. The maximum gap is reached in samples of near-stoichiometric composition.