Abstract
The transition from an indirect to a direct gap semiconductor in unstrained as well as compressively and tensile strained SnxGe1−x alloys is investigated as a function of the Sn content 0 ≤ x ≤ 1 by means of both a very accurate supercell approach and the more approximate virtual crystal approximation (VCA). In the local density approximation we calculate the bowing parameter of the lattice constant of unstrained SnxGe1−x alloys. Provided that pseudopotentials suitable for the VCA are used, the random supercell and VCA approaches yield consistent bowing parameters for the lattice constant of −0.21 and −0.28 Å, respectively, in the entire Sn concentration range. The band structures and energy gaps are calculated using the modified Becke-Johnson potential, which, for Ge, yields a one-electron band gap in very good agreement with experimental data. The crossover from an indirect to a direct gap semiconducting alloy is determined at about 4.5% Sn in unstrained SnxGe1−x. When SnxGe1−x is grown commensurately and thus strained on Ge(100), a transition to a direct gap is also observed but at Sn concentrations of about 10%. We finally predict the direct and indirect band gaps as a function of the in-plane lattice constant and Sn concentration for SnxGe1−x alloys grown on (100) substrates.
Original language | English |
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Article number | 165201 |
Number of pages | 9 |
Journal | Physical Review B |
Volume | 89 |
Issue number | 16 |
DOIs | |
Publication status | Published - 9 Apr 2014 |
Austrian Fields of Science 2012
- 103009 Solid state physics
- 103015 Condensed matter
- 103025 Quantum mechanics
- 103036 Theoretical physics
Keywords
- AUGMENTED-WAVE METHOD
- GE1-XSNX ALLOYS
- BAND-STRUCTURE
- ELECTRON-GAS
- APPROXIMATION
- GE