A proximal gradient method for ensemble density functional theory

Michael Ulbrich; Zaiwen Wen; Chao Yang; Dennis Klöckner; Zhaosong Lu

doi:10.1137/14098973X

A proximal gradient method for ensemble density functional theory

Michael Ulbrich, Zaiwen Wen, Chao Yang, Dennis Klöckner, Zhaosong Lu

Research output: Contribution to journal › Review article › peer-review

14 Scopus citations

Abstract

The ensemble density functional theory (E-DFT) is valuable for simulations of metallic systems due to the absence of a gap in the spectrum of the Hamiltonian matrices. Although the widely used self-consistent field (SCF) iteration method can be extended to solve the minimization of the total energy functional with respect to orthogonality constraints, there is no theoretical guarantee on the convergence of these algorithms. In this paper, we consider an equivalent model with a single variable and a single spherical constraint by eliminating the dependence on the fractional occupancies. A proximal gradient method is developed by keeping the entropy term but linearizing all other terms in the total energy functional. Convergence to the stationary point is established. Numerical results using the MATLAB toolbox KSSOLV can outperform SCF consistently on many metallic systems.

Original language	English (US)
Pages (from-to)	A1975-A2002
Journal	SIAM Journal on Scientific Computing
Volume	37
Issue number	4
DOIs	https://doi.org/10.1137/14098973X
State	Published - 2015
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2015 Society for Industrial and Applied Mathematics.

Keywords

Ensemble density functional theory
Kohn-Sham total energy minimization
Orthogonality/spherical constraints
Proximal gradient method

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abstract = "The ensemble density functional theory (E-DFT) is valuable for simulations of metallic systems due to the absence of a gap in the spectrum of the Hamiltonian matrices. Although the widely used self-consistent field (SCF) iteration method can be extended to solve the minimization of the total energy functional with respect to orthogonality constraints, there is no theoretical guarantee on the convergence of these algorithms. In this paper, we consider an equivalent model with a single variable and a single spherical constraint by eliminating the dependence on the fractional occupancies. A proximal gradient method is developed by keeping the entropy term but linearizing all other terms in the total energy functional. Convergence to the stationary point is established. Numerical results using the MATLAB toolbox KSSOLV can outperform SCF consistently on many metallic systems.",

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AU - Ulbrich, Michael

AU - Wen, Zaiwen

AU - Yang, Chao

AU - Klöckner, Dennis

AU - Lu, Zhaosong

PY - 2015

Y1 - 2015

N2 - The ensemble density functional theory (E-DFT) is valuable for simulations of metallic systems due to the absence of a gap in the spectrum of the Hamiltonian matrices. Although the widely used self-consistent field (SCF) iteration method can be extended to solve the minimization of the total energy functional with respect to orthogonality constraints, there is no theoretical guarantee on the convergence of these algorithms. In this paper, we consider an equivalent model with a single variable and a single spherical constraint by eliminating the dependence on the fractional occupancies. A proximal gradient method is developed by keeping the entropy term but linearizing all other terms in the total energy functional. Convergence to the stationary point is established. Numerical results using the MATLAB toolbox KSSOLV can outperform SCF consistently on many metallic systems.

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KW - Kohn-Sham total energy minimization

KW - Orthogonality/spherical constraints

KW - Proximal gradient method

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A proximal gradient method for ensemble density functional theory

Abstract

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Keywords

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