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Paper detail

Multiband tight--binding approach to tunneling in semiconductor heterostructures: Application to $ΓX$ transfer in GaAs

We study tunneling in semiconductor heterostructures where the constituent materials can have a direct or indirect bandgap. In order to have a good description of the lowest conduction band, we have used the nearest-- neighbour $sp^3s^*$ tight--binding model put forward by P. Vogl {\em et al.}. A recursive Green--function method yields transmission coefficients from which an expression for the current density may be written down. The method is applied to GaAs/AlAs heterostructures. Electrons may traverse the AlAs barriers via different tunneling states $ψ_Γ$ and $ψ_X$ ($ΓX$ mixing). With an applied bias $V>0.5$ V electrons may enter the GaAs collector contact in both the $Γ$ and the $X$ valley ($ΓX$ transfer). We have studied a number of GaAs/AlAs structures. For very narrow barriers there is little $ΓX$ transfer, but AlAs barriers wider than about 25 Åact as ``$ΓX$ filters'', i.e., most transmitted electrons have been transfered to the $X$ valley.

preprint1993arXivOpen access
J. A. StøvnengP. Lipavský
cond-mat
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J. A. StøvnengP. Lipavský

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