Title of article
A generalized plane-wave formulation of formalism and continuum-elasticity approach to elastic and electronic properties of semiconductor nanostructures
Author/Authors
Marquardt، نويسنده , , Oliver and Boeck، نويسنده , , Sixten and Freysoldt، نويسنده , , Christoph and Hickel، نويسنده , , Tilmann and Schulz، نويسنده , , Stefan and Neugebauer، نويسنده , , J?rg and O’Reilly، نويسنده , , Eoin P.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
8
From page
280
To page
287
Abstract
We present a generalized and flexible plane-wave based implementation of the multiband k · p formalism to study the electronic properties of semiconductor nanostructures. All ingredients of the modeling process, namely the Hamiltonian, the nanostructure’s geometry and the required material parameters, are defined in human-readable input files that can be easily generated and modified. The generalized k · p model can contain an arbitrary number of directly treated bands as well as strain, piezoelectric, and external potentials. All calculations can be performed for arbitrary crystal structures. The nanostructure is described in terms of a real-space composition map that may contain an arbitrary number of base compounds and alloys. We demonstrate the applicability and flexibility of our implementation for the example of (111)-oriented, site-controlled InGaAs quantum dots, where a rotated eight-band k · p Hamiltonian is employed. As a second example, a 14-band k · p model that captures the bulk inversion asymmetry of the zinc-blende lattice is applied for the case of a pyramidal (0 0 1)-oriented InAs/GaAs quantum dot. Here we show that the explicit treatment of 14 bands removes the well known shortcoming of eight-band k · p models for (0 0 1)-oriented zinc-blende quantum dots which leads to artificially degenerate p-like electron states.
Keywords
k · p Formalism , Continuum-elasticity theory , plane wave , Nanostructures , Electronic structure
Journal title
Computational Materials Science
Serial Year
2014
Journal title
Computational Materials Science
Record number
1693398
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