Periodic schrödinger operators with local defects and spectral pollution

Eric Cancès; Virginie Ehrlacher; Yvon Maday

doi:10.1137/110855545

Periodic schrödinger operators with local defects and spectral pollution

Eric Cancès, Virginie Ehrlacher, Yvon Maday

Research output: Contribution to journal › Article › peer-review

Abstract

This article deals with the numerical calculation of eigenvalues of perturbed periodic Schrödinger operators located in spectral gaps. Such operators are encountered in the modeling of the electronic structure of crystals with local defects and of photonic crystals. The usual finite element Galerkin approximation is known to give rise to spectral pollution. In this article, we give a precise description of the corresponding spurious states. We then prove that the supercell model does not produce spectral pollution. Finally, we extend results by Lewin and Séré on some no-pollution criteria. In particular, we prove that using approximate spectral projectors enables one to eliminate spectral pollution in a given spectral gap of the reference periodic Schrödinger operator.

Original language	English
Pages (from-to)	3016-3035
Number of pages	20
Journal	SIAM Journal on Numerical Analysis
Volume	50
Issue number	6
DOIs	https://doi.org/10.1137/110855545
Publication status	Published - 1 Jan 2012

Keywords

Eigenvalue problem
Photonic crystal
Schrödinger equation
Spectral pollution
Supercell

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10.1137/110855545

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title = "Periodic schr{\"o}dinger operators with local defects and spectral pollution",

abstract = "This article deals with the numerical calculation of eigenvalues of perturbed periodic Schr{\"o}dinger operators located in spectral gaps. Such operators are encountered in the modeling of the electronic structure of crystals with local defects and of photonic crystals. The usual finite element Galerkin approximation is known to give rise to spectral pollution. In this article, we give a precise description of the corresponding spurious states. We then prove that the supercell model does not produce spectral pollution. Finally, we extend results by Lewin and S{\'e}r{\'e} on some no-pollution criteria. In particular, we prove that using approximate spectral projectors enables one to eliminate spectral pollution in a given spectral gap of the reference periodic Schr{\"o}dinger operator.",

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author = "Eric Canc{\`e}s and Virginie Ehrlacher and Yvon Maday",

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AU - Cancès, Eric

AU - Ehrlacher, Virginie

AU - Maday, Yvon

PY - 2012/1/1

Y1 - 2012/1/1

N2 - This article deals with the numerical calculation of eigenvalues of perturbed periodic Schrödinger operators located in spectral gaps. Such operators are encountered in the modeling of the electronic structure of crystals with local defects and of photonic crystals. The usual finite element Galerkin approximation is known to give rise to spectral pollution. In this article, we give a precise description of the corresponding spurious states. We then prove that the supercell model does not produce spectral pollution. Finally, we extend results by Lewin and Séré on some no-pollution criteria. In particular, we prove that using approximate spectral projectors enables one to eliminate spectral pollution in a given spectral gap of the reference periodic Schrödinger operator.

AB - This article deals with the numerical calculation of eigenvalues of perturbed periodic Schrödinger operators located in spectral gaps. Such operators are encountered in the modeling of the electronic structure of crystals with local defects and of photonic crystals. The usual finite element Galerkin approximation is known to give rise to spectral pollution. In this article, we give a precise description of the corresponding spurious states. We then prove that the supercell model does not produce spectral pollution. Finally, we extend results by Lewin and Séré on some no-pollution criteria. In particular, we prove that using approximate spectral projectors enables one to eliminate spectral pollution in a given spectral gap of the reference periodic Schrödinger operator.

KW - Eigenvalue problem

KW - Photonic crystal

KW - Schrödinger equation

KW - Spectral pollution

KW - Supercell

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VL - 50

SP - 3016

EP - 3035

JO - SIAM Journal on Numerical Analysis

JF - SIAM Journal on Numerical Analysis

IS - 6

ER -

Periodic schrödinger operators with local defects and spectral pollution

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Keywords

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