Maximal symetrization and reduction of fields: application to wavefunctions in solid state nanostructures

A novel general formalism for the maximal symetrization and reduction of fields (MSRF) is proposed and applied to wavefunctions in solid state nanostructures. Its primary target is to provide an essential tool for the study and analysis of the electronic and optical properties of semiconductor quant...

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Bibliographic Details
Published inarXiv.org
Main Authors Dalessi, S, M -A Dupertuis
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 04.03.2010
Subjects
Boundary conditions
Domains
Eigenvectors
Formalism
Heterostructures
Mathematical analysis
Maxwell's equations
Nanostructure
Optical properties
Partial differential equations
Physics - Mesoscale and Nanoscale Physics
Physics - Other Condensed Matter
Quantum wires
Reduction
Solid state
Symmetry
Wave functions
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Summary:A novel general formalism for the maximal symetrization and reduction of fields (MSRF) is proposed and applied to wavefunctions in solid state nanostructures. Its primary target is to provide an essential tool for the study and analysis of the electronic and optical properties of semiconductor quantum heterostructures with relatively high point-group symmetry, and studied with the \(k\cdot p\) formalism. Nevertheless the approach is valid in a much larger framework than \(k\cdot p\) theory, it is applicable to arbitrary systems of coupled partial differential equations (e.g. strain equations or Maxwell equations). For spinless problems (scalar equations), one can use a systematic Spatial Domain Reduction (SDR) technique which allows, for every irreducible representation, to reduce the set of equations on a minimal domain with automatic incorporation of the boundary conditions at the border, which are shown to be non-trivial in general. For a vectorial or spinorial set of functions, the SDR technique must be completed by the use of an optimal basis in vectorial or spinorial space (in a crystal we call it the Optimal Bloch function Basis - OBB). The advantages are numerous: sharper insights on the symmetry properties of every eigenstate, minimal coupling schemes, analytically and computationally exploitable at the component function level, minimal computing domains. The formalism can be applied also as a postprocessing operation, offering all subsequent analytical and computationnal advantages of symmetrization. The specific case of a quantum wire (QWRs) with \(C_{3v}\) point group symmetry is used as a concrete illustration of the application of MSRF.
ISSN:2331-8422
DOI:10.48550/arxiv.0908.3846