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Direct bandgap optical transitions in Si nanocrystals

Materials Science 2015-05-13 v3
Authors: A. A. Prokofiev , A. S. Moskalenko , I. N. Yassievich , W. D. A. M. de Boer , D. Timmerman , H. Zhang , W. J. Buma , T. Gregorkiewicz
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Abstract

The effect of quantum confinement on the direct bandgap of spherical Si nanocrystals has been modelled theoretically. We conclude that the energy of the direct bandgap at the Γ\Gamma-point decreases with size reduction: quantum confinement enhances radiative recombination across the direct bandgap and introduces its "red" shift for smaller grains. We postulate to identify the frequently reported efficient blue emission (F-band) from Si nanocrystals with this zero-phonon recombination. In a dedicated experiment, we confirm the "red" shift of the F-band, supporting the proposed identification.

Cite

@article{arxiv.0901.4268,
  title  = {Direct bandgap optical transitions in Si nanocrystals},
  author = {A. A. Prokofiev and A. S. Moskalenko and I. N. Yassievich and W. D. A. M. de Boer and D. Timmerman and H. Zhang and W. J. Buma and T. Gregorkiewicz},
  journal= {arXiv preprint arXiv:0901.4268},
  year   = {2015}
}

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