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Ab-initio Prediction of Conduction Band Spin Splitting in Zincblende Semiconductors

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 Publication date 2005
  fields Physics
and research's language is English




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We use a recently developed self-consistent $GW$ approximation to present systematic emph{ab initio} calculations of the conduction band spin splitting in III-V and II-V zincblende semiconductors. The spin orbit interaction is taken into account as a perturbation to the scalar relativistic hamiltonian. These are the first calculations of conduction band spin splittings based on a quasiparticle approach; and because the self-consistent $GW$ scheme accurately reproduces the relevant band parameters, it is expected to be a reliable predictor of spin splittings. The results are compared to the few available experimental data and a previous calculation based on a model one-particle potential. We also briefly address the widely used {bf k}$cdot${bf p} parameterization in the context of these results.



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