2010
DOI: 10.1137/060651653
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Numerical Methods for Electronic Structure Calculations of Materials

Abstract: The goal of this article is to give an overview of numerical problems encountered when determining the electronic structure of materials and the rich variety of techniques used to solve these problems. The paper is intended for a diverse scienti£c computing audience. For this reason, we assume the reader does not have an extensive background in the related physics. Our overview focuses on the nature of the numerical problems to be solved, their origin, and on the methods used to solve the resulting linear alge… Show more

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Cited by 273 publications
(168 citation statements)
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“…(Here the transpose actually refers to the Hermitian conjugate since the wavefunction ψ i (r) is a complex quantity.) Thus, the magnitude of this entry as well as other derived quantities like the trace of ρ give empirically-measurable quantities; see, e.g., Section 6.2 of [180]. More practically, improved methods for estimating the diagonal of a projection matrix may have significant implications for leading to improvements in large-scale numerical computations in scientific computing applications such as the density functional theory of many-atom systems [180,181].…”
Section: Statistical Leverage In Large-scale Data Analysismentioning
confidence: 99%
“…(Here the transpose actually refers to the Hermitian conjugate since the wavefunction ψ i (r) is a complex quantity.) Thus, the magnitude of this entry as well as other derived quantities like the trace of ρ give empirically-measurable quantities; see, e.g., Section 6.2 of [180]. More practically, improved methods for estimating the diagonal of a projection matrix may have significant implications for leading to improvements in large-scale numerical computations in scientific computing applications such as the density functional theory of many-atom systems [180,181].…”
Section: Statistical Leverage In Large-scale Data Analysismentioning
confidence: 99%
“…U(q) denotes either the classical potential energy function [29], or the Kohn-Sham total energy [30,31]. In what follows, we will focus on the latter problem.…”
Section: Theorymentioning
confidence: 99%
“…This state of affair is evident when examining survey articles and reference books on eigenvalue and/or singular value computations (e.g., [19,7,25,22,10]). On the other hand, large-scale but unstructured matrices do arise from applications, such as image processing and computational materials science (e.g., [27,20]), which involve large amounts of data even though their dimensions are relatively small compared to those of large sparse matrices. This is especially true in recent years when the demand for computing dominant SVDs of large unstructured matrices has become increasingly pervasive in dataintensive applications.…”
Section: During Decades Of Research Numerous Iterative Algorithms Hamentioning
confidence: 99%