How to verify the precision of density-functional-theory implementations via reproducible and universal workflows

Emanuele Bosoni; Louis Beal; Marnik Bercx; Peter Blaha; Stefan Blügel; Jens Bröder; Martin Callsen; Stefaan Cottenier; Augustin Degomme; Vladimir Dikan; Kristjan Eimre; Espen Flage-Larsen; Marco Fornari; Alberto Garcia; Luigi Genovese; Matteo Giantomassi; Sebastiaan P. Huber; Henning Janssen; Georg Kastlunger; Matthias Krack; Georg Kresse; Thomas D. Kühne; Kurt Lejaeghere; Georg K.H. Madsen; Martijn Marsman; Nicola Marzari; Gregor Michalicek; Hossein Mirhosseini; Tiziano M.A. Müller; Guido Petretto; Chris J. Pickard; Samuel Poncé; Gian Marco Rignanese; Oleg Rubel; Thomas Ruh; Michael Sluydts; Danny E.P. Vanpoucke; Sudarshan Vijay; Michael Wolloch; Daniel Wortmann; Aliaksandr V. Yakutovich; Jusong Yu; Austin Zadoks; Bonan Zhu; Giovanni Pizzi

doi:10.1038/s42254-023-00655-3

How to verify the precision of density-functional-theory implementations via reproducible and universal workflows

Emanuele Bosoni, Louis Beal, Marnik Bercx, Peter Blaha, Stefan Blügel, Jens Bröder, Martin Callsen, Stefaan Cottenier, Augustin Degomme, Vladimir Dikan, Kristjan Eimre, Espen Flage-Larsen, Marco Fornari, Alberto Garcia, Luigi Genovese, Matteo Giantomassi, Sebastiaan P. Huber, Henning Janssen, Georg Kastlunger, Matthias KrackGeorg Kresse, Thomas D. Kühne, Kurt Lejaeghere, Georg K.H. Madsen, Martijn Marsman, Nicola Marzari, Gregor Michalicek, Hossein Mirhosseini, Tiziano M.A. Müller, Guido Petretto, Chris J. Pickard, Samuel Poncé, Gian Marco Rignanese, Oleg Rubel, Thomas Ruh, Michael Sluydts, Danny E.P. Vanpoucke, Sudarshan Vijay, Michael Wolloch, Daniel Wortmann, Aliaksandr V. Yakutovich, Jusong Yu, Austin Zadoks, Bonan Zhu, Giovanni Pizzi (Corresponding author)

Computational Materials Physics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Density-functional theory methods and codes adopting periodic boundary conditions are extensively used in condensed matter physics and materials science research. In 2016, their precision (how well properties computed with different codes agree among each other) was systematically assessed on elemental crystals: a first crucial step to evaluate the reliability of such computations. In this Expert Recommendation, we discuss recommendations for verification studies aiming at further testing precision and transferability of density-functional-theory computational approaches and codes. We illustrate such recommendations using a greatly expanded protocol covering the whole periodic table from Z = 1 to 96 and characterizing 10 prototypical cubic compounds for each element: four unaries and six oxides, spanning a wide range of coordination numbers and oxidation states. The primary outcome is a reference dataset of 960 equations of state cross-checked between two all-electron codes, then used to verify and improve nine pseudopotential-based approaches. Finally, we discuss the extent to which the current results for total energies can be reused for different goals.

Original language	English
Pages (from-to)	45–58
Number of pages	14
Journal	Nature Reviews Physics
Volume	6
Early online date	14 Nov 2023
DOIs	https://doi.org/10.1038/s42254-023-00655-3
Publication status	Published - Jan 2024

Austrian Fields of Science 2012

103015 Condensed matter
103043 Computational physics

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Bosoni, E., Beal, L., Bercx, M., Blaha, P., Blügel, S., Bröder, J., Callsen, M., Cottenier, S., Degomme, A., Dikan, V., Eimre, K., Flage-Larsen, E., Fornari, M., Garcia, A., Genovese, L., Giantomassi, M., Huber, S. P., Janssen, H., Kastlunger, G., ... Pizzi, G. (2024). How to verify the precision of density-functional-theory implementations via reproducible and universal workflows. Nature Reviews Physics, 6, 45–58. https://doi.org/10.1038/s42254-023-00655-3

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title = "How to verify the precision of density-functional-theory implementations via reproducible and universal workflows",

abstract = "Density-functional theory methods and codes adopting periodic boundary conditions are extensively used in condensed matter physics and materials science research. In 2016, their precision (how well properties computed with different codes agree among each other) was systematically assessed on elemental crystals: a first crucial step to evaluate the reliability of such computations. In this Expert Recommendation, we discuss recommendations for verification studies aiming at further testing precision and transferability of density-functional-theory computational approaches and codes. We illustrate such recommendations using a greatly expanded protocol covering the whole periodic table from Z = 1 to 96 and characterizing 10 prototypical cubic compounds for each element: four unaries and six oxides, spanning a wide range of coordination numbers and oxidation states. The primary outcome is a reference dataset of 960 equations of state cross-checked between two all-electron codes, then used to verify and improve nine pseudopotential-based approaches. Finally, we discuss the extent to which the current results for total energies can be reused for different goals.",

author = "Emanuele Bosoni and Louis Beal and Marnik Bercx and Peter Blaha and Stefan Bl{\"u}gel and Jens Br{\"o}der and Martin Callsen and Stefaan Cottenier and Augustin Degomme and Vladimir Dikan and Kristjan Eimre and Espen Flage-Larsen and Marco Fornari and Alberto Garcia and Luigi Genovese and Matteo Giantomassi and Huber, {Sebastiaan P.} and Henning Janssen and Georg Kastlunger and Matthias Krack and Georg Kresse and K{\"u}hne, {Thomas D.} and Kurt Lejaeghere and Madsen, {Georg K.H.} and Martijn Marsman and Nicola Marzari and Gregor Michalicek and Hossein Mirhosseini and M{\"u}ller, {Tiziano M.A.} and Guido Petretto and Pickard, {Chris J.} and Samuel Ponc{\'e} and Rignanese, {Gian Marco} and Oleg Rubel and Thomas Ruh and Michael Sluydts and Vanpoucke, {Danny E.P.} and Sudarshan Vijay and Michael Wolloch and Daniel Wortmann and Yakutovich, {Aliaksandr V.} and Jusong Yu and Austin Zadoks and Bonan Zhu and Giovanni Pizzi",

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Bosoni, E, Beal, L, Bercx, M, Blaha, P, Blügel, S, Bröder, J, Callsen, M, Cottenier, S, Degomme, A, Dikan, V, Eimre, K, Flage-Larsen, E, Fornari, M, Garcia, A, Genovese, L, Giantomassi, M, Huber, SP, Janssen, H, Kastlunger, G, Krack, M, Kresse, G, Kühne, TD, Lejaeghere, K, Madsen, GKH, Marsman, M, Marzari, N, Michalicek, G, Mirhosseini, H, Müller, TMA, Petretto, G, Pickard, CJ, Poncé, S, Rignanese, GM, Rubel, O, Ruh, T, Sluydts, M, Vanpoucke, DEP, Vijay, S, Wolloch, M, Wortmann, D, Yakutovich, AV, Yu, J, Zadoks, A, Zhu, B & Pizzi, G 2024, 'How to verify the precision of density-functional-theory implementations via reproducible and universal workflows', Nature Reviews Physics, vol. 6, pp. 45–58. https://doi.org/10.1038/s42254-023-00655-3

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T1 - How to verify the precision of density-functional-theory implementations via reproducible and universal workflows

AU - Bosoni, Emanuele

AU - Beal, Louis

AU - Bercx, Marnik

AU - Blaha, Peter

AU - Blügel, Stefan

AU - Bröder, Jens

AU - Callsen, Martin

AU - Cottenier, Stefaan

AU - Degomme, Augustin

AU - Dikan, Vladimir

AU - Eimre, Kristjan

AU - Flage-Larsen, Espen

AU - Fornari, Marco

AU - Garcia, Alberto

AU - Genovese, Luigi

AU - Giantomassi, Matteo

AU - Huber, Sebastiaan P.

AU - Janssen, Henning

AU - Kastlunger, Georg

AU - Krack, Matthias

AU - Kresse, Georg

AU - Kühne, Thomas D.

AU - Lejaeghere, Kurt

AU - Madsen, Georg K.H.

AU - Marsman, Martijn

AU - Marzari, Nicola

AU - Michalicek, Gregor

AU - Mirhosseini, Hossein

AU - Müller, Tiziano M.A.

AU - Petretto, Guido

AU - Pickard, Chris J.

AU - Poncé, Samuel

AU - Rignanese, Gian Marco

AU - Rubel, Oleg

AU - Ruh, Thomas

AU - Sluydts, Michael

AU - Vanpoucke, Danny E.P.

AU - Vijay, Sudarshan

AU - Wolloch, Michael

AU - Wortmann, Daniel

AU - Yakutovich, Aliaksandr V.

AU - Yu, Jusong

AU - Zadoks, Austin

AU - Zhu, Bonan

AU - Pizzi, Giovanni

PY - 2024/1

Y1 - 2024/1

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AB - Density-functional theory methods and codes adopting periodic boundary conditions are extensively used in condensed matter physics and materials science research. In 2016, their precision (how well properties computed with different codes agree among each other) was systematically assessed on elemental crystals: a first crucial step to evaluate the reliability of such computations. In this Expert Recommendation, we discuss recommendations for verification studies aiming at further testing precision and transferability of density-functional-theory computational approaches and codes. We illustrate such recommendations using a greatly expanded protocol covering the whole periodic table from Z = 1 to 96 and characterizing 10 prototypical cubic compounds for each element: four unaries and six oxides, spanning a wide range of coordination numbers and oxidation states. The primary outcome is a reference dataset of 960 equations of state cross-checked between two all-electron codes, then used to verify and improve nine pseudopotential-based approaches. Finally, we discuss the extent to which the current results for total energies can be reused for different goals.

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How to verify the precision of density-functional-theory implementations via reproducible and universal workflows

Abstract

Austrian Fields of Science 2012

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BIG-MAP: Battery Interface Genome - Materials Acceleration Platform

High-throughput methods for ab-initio interface tribology

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How to verify the precision of density-functional-theory implementations via reproducible and universal workflows

Abstract

Austrian Fields of Science 2012

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Other files and links

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BIG-MAP: Battery Interface Genome - Materials Acceleration Platform

High-throughput methods for ab-initio interface tribology

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