Ehrenfest dynamics with localized atomic-orbital basis sets within the projector augmented-wave method

Vladimír Zobač; Mikael Kuisma; Ask Hjorth Larsen; Tuomas Rossi; Toma Susi

doi:10.1063/5.0252559

Ehrenfest dynamics with localized atomic-orbital basis sets within the projector augmented-wave method

Vladimír Zobač^*
, Mikael Kuisma
, Ask Hjorth Larsen
, Tuomas Rossi
, Toma Susi^*

^*Corresponding author for this work

University of Vienna
Aalto University

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

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Abstract

Density functional theory with linear combination of atomic orbitals (LCAO) basis sets is useful for studying large atomic systems, especially when it comes to computationally highly demanding time-dependent dynamics. We have implemented the Ehrenfest molecular dynamics (ED) method with the approximate approach of Tomfohr and Sankey within the projector augmented-wave code GPAW. We apply this method to small molecules as well as larger periodic systems and elucidate its limits, advantages, and disadvantages in comparison with the existing implementation of Ehrenfest dynamics with a real-space grid representation. For modest atomic velocities, LCAO-ED shows satisfactory accuracy at a much reduced computational cost. This method will be particularly useful for modeling ion irradiation processes that require large amounts of vacuum in the simulation cell.

Original language	English
Article number	124117
Journal	Journal of Chemical Physics
Volume	162
Issue number	12
Number of pages	8
ISSN	0021-9606
DOIs	https://doi.org/10.1063/5.0252559
Publication status	Published - 2025

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title = "Ehrenfest dynamics with localized atomic-orbital basis sets within the projector augmented-wave method",

abstract = "Density functional theory with linear combination of atomic orbitals (LCAO) basis sets is useful for studying large atomic systems, especially when it comes to computationally highly demanding time-dependent dynamics. We have implemented the Ehrenfest molecular dynamics (ED) method with the approximate approach of Tomfohr and Sankey within the projector augmented-wave code GPAW. We apply this method to small molecules as well as larger periodic systems and elucidate its limits, advantages, and disadvantages in comparison with the existing implementation of Ehrenfest dynamics with a real-space grid representation. For modest atomic velocities, LCAO-ED shows satisfactory accuracy at a much reduced computational cost. This method will be particularly useful for modeling ion irradiation processes that require large amounts of vacuum in the simulation cell.",

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AU - Zobač, Vladimír

AU - Kuisma, Mikael

AU - Larsen, Ask Hjorth

AU - Rossi, Tuomas

AU - Susi, Toma

PY - 2025

Y1 - 2025

N2 - Density functional theory with linear combination of atomic orbitals (LCAO) basis sets is useful for studying large atomic systems, especially when it comes to computationally highly demanding time-dependent dynamics. We have implemented the Ehrenfest molecular dynamics (ED) method with the approximate approach of Tomfohr and Sankey within the projector augmented-wave code GPAW. We apply this method to small molecules as well as larger periodic systems and elucidate its limits, advantages, and disadvantages in comparison with the existing implementation of Ehrenfest dynamics with a real-space grid representation. For modest atomic velocities, LCAO-ED shows satisfactory accuracy at a much reduced computational cost. This method will be particularly useful for modeling ion irradiation processes that require large amounts of vacuum in the simulation cell.

AB - Density functional theory with linear combination of atomic orbitals (LCAO) basis sets is useful for studying large atomic systems, especially when it comes to computationally highly demanding time-dependent dynamics. We have implemented the Ehrenfest molecular dynamics (ED) method with the approximate approach of Tomfohr and Sankey within the projector augmented-wave code GPAW. We apply this method to small molecules as well as larger periodic systems and elucidate its limits, advantages, and disadvantages in comparison with the existing implementation of Ehrenfest dynamics with a real-space grid representation. For modest atomic velocities, LCAO-ED shows satisfactory accuracy at a much reduced computational cost. This method will be particularly useful for modeling ion irradiation processes that require large amounts of vacuum in the simulation cell.

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VL - 162

JO - Journal of Chemical Physics

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ER -

Ehrenfest dynamics with localized atomic-orbital basis sets within the projector augmented-wave method

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