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Computational design of direct-bandgap semiconductors that lattice-match silicon

Author

Listed:
  • Peihong Zhang

    (The Pennsylvania State University, 104 Davey Lab)

  • Vincent H. Crespi

    (The Pennsylvania State University, 104 Davey Lab)

  • Eric Chang

    (University of California at Berkeley
    Lawrence Berkeley Laboratory)

  • Steven G. Louie

    (University of California at Berkeley
    Lawrence Berkeley Laboratory)

  • Marvin L. Cohen

    (University of California at Berkeley
    Lawrence Berkeley Laboratory)

Abstract

Crystalline silicon is an indirect-bandgap semiconductor, making it an inefficient emitter of light. The successful integration of silicon-based electronics with optical components will therefore require optically active (for example, direct-bandgap) materials that can be grown on silicon with high-quality interfaces. For well ordered materials, this effectively translates into the requirement that such materials lattice-match silicon: lattice mismatch generally causes cracks and poor interface properties once the mismatched overlayer exceeds a very thin critical thickness. But no direct-bandgap semiconductor has yet been produced that can lattice-match silicon, and previously suggested structures1 pose formidable challenges for synthesis. Much recent work has therefore focused on introducing compliant transition layers between the mismatched components2,3,4. Here we propose a more direct solution to integrating silicon electronics with optical components. We have computationally designed two hypothetical direct-bandgap semiconductor alloys, the synthesis of which should be possible through the deposition of specific group-IV precursor molecules5,6 and which lattice-match silicon to 0.5–1% along lattice planes with low Miller indices. The calculated bandgaps (and hence the frequency of emitted light) lie in the window of minimal absorption in current optical fibres.

Suggested Citation

  • Peihong Zhang & Vincent H. Crespi & Eric Chang & Steven G. Louie & Marvin L. Cohen, 2001. "Computational design of direct-bandgap semiconductors that lattice-match silicon," Nature, Nature, vol. 409(6816), pages 69-71, January.
  • Handle: RePEc:nat:nature:v:409:y:2001:i:6816:d:10.1038_35051054
    DOI: 10.1038/35051054
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    Cited by:

    1. Lin-Ding Yuan & Shu-Shen Li & Jun-Wei Luo, 2024. "Direct bandgap emission from strain-doped germanium," Nature Communications, Nature, vol. 15(1), pages 1-7, December.

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