Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials

George A. Marchant; Miguel A. Caro; Bora Karasulu; Livia B. Pártay

doi:10.1038/s41524-023-01081-w

Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials

George A. Marchant^*, Miguel A. Caro, Bora Karasulu, Livia B. Pártay^*

^*Tämän työn vastaava kirjoittaja

University of Warwick

Tutkimustuotos: Lehtiartikkeli › Article › Scientific › vertaisarvioitu

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Abstrakti

We demonstrate how the many-body potential energy landscape of carbon can be explored with the nested sampling algorithm, allowing for the calculation of its pressure-temperature phase diagram. We compare four interatomic potential models: Tersoff, EDIP, GAP-20 and its recently updated version, GAP-20U. Our evaluation is focused on their macroscopic properties, melting transitions, and identifying thermodynamically stable solid structures up to at least 100 GPa. The phase diagrams of the GAP models show good agreement with experimental results. However, we find that the models’ description of graphite includes thermodynamically stable phases with incorrect layer spacing. By adding a suitable selection of structures to the database and re-training the potential, we have derived an improved model — GAP-20U+gr — that suppresses erroneous local minima in the graphitic energy landscape. At extreme high pressure nested sampling identifies two novel stable structures in the GAP-20 model, however, the stability of these is not confirmed by electronic structure calculations, highlighting routes to further extend the applicability of the GAP models.

Alkuperäiskieli	Englanti
Artikkeli	131
Sivumäärä	12
Julkaisu	npj Computational Materials
Vuosikerta	9
Numero	1
DOI - pysyväislinkit	https://doi.org/10.1038/s41524-023-01081-w
Tila	Julkaistu - 27 heinäk. 2023
OKM-julkaisutyyppi	A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä

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10.1038/s41524-023-01081-wLisenssi: CC BY

CHEM_Marchant_et_al_Exploring_the_configuration_2023_npj_Computational_MaterialsFinal published version, 4,11 MBLisenssi: CC BY

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Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials
Marchant, G. A. (Creator), Caro Bayo, M. (Creator), Karasulu, B. (Creator) & Partay, L. B. (Creator), Zenodo, 20 jouluk. 2022
DOI - pysyväislinkki: 10.5281/zenodo.7463705, https://zenodo.org/record/7463706
Tietoaineisto: Dataset

NEXTCELL: Next generation interatomic potentials to simulate new cellulose based materials
Caro Bayo, M.
01/09/2020 → 31/08/2025
Projekti: Academy of Finland: Other research funding

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title = "Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials",

abstract = "We demonstrate how the many-body potential energy landscape of carbon can be explored with the nested sampling algorithm, allowing for the calculation of its pressure-temperature phase diagram. We compare four interatomic potential models: Tersoff, EDIP, GAP-20 and its recently updated version, GAP-20U. Our evaluation is focused on their macroscopic properties, melting transitions, and identifying thermodynamically stable solid structures up to at least 100 GPa. The phase diagrams of the GAP models show good agreement with experimental results. However, we find that the models{\textquoteright} description of graphite includes thermodynamically stable phases with incorrect layer spacing. By adding a suitable selection of structures to the database and re-training the potential, we have derived an improved model — GAP-20U+gr — that suppresses erroneous local minima in the graphitic energy landscape. At extreme high pressure nested sampling identifies two novel stable structures in the GAP-20 model, however, the stability of these is not confirmed by electronic structure calculations, highlighting routes to further extend the applicability of the GAP models.",

author = "Marchant, {George A.} and Caro, {Miguel A.} and Bora Karasulu and P{\'a}rtay, {Livia B.}",

note = "Funding Information: The authors thank Nigel Marks for providing access to the carbon EDIP. The authors also thank Albert P. Bart{\'o}k, G{\'a}bor Cs{\'a}nyi and Volker Deringer for useful discussions around the performance of the GAP-20 model. L.B.P. and B.K. acknowledge support from the EPSRC through the individual Early Career Fellowships (LBP: EP/T000163/1 and BK: EP/T026138/1). M.A.C. acknowledges personal funding from the Academy of Finland, under project #330488. Computing facilities were provided by the Scientific Computing Research Technology Platform of the University of Warwick. Calculations using the GAP potential were performed using the Sulis Tier 2 HPC platform hosted by the Scientific Computing Research Technology Platform at the University of Warwick. Sulis is funded by EPSRC Grant EP/T022108/1 and the HPC Midlands+ consortium.",

year = "2023",

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doi = "10.1038/s41524-023-01081-w",

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AU - Pártay, Livia B.

N1 - Funding Information: The authors thank Nigel Marks for providing access to the carbon EDIP. The authors also thank Albert P. Bartók, Gábor Csányi and Volker Deringer for useful discussions around the performance of the GAP-20 model. L.B.P. and B.K. acknowledge support from the EPSRC through the individual Early Career Fellowships (LBP: EP/T000163/1 and BK: EP/T026138/1). M.A.C. acknowledges personal funding from the Academy of Finland, under project #330488. Computing facilities were provided by the Scientific Computing Research Technology Platform of the University of Warwick. Calculations using the GAP potential were performed using the Sulis Tier 2 HPC platform hosted by the Scientific Computing Research Technology Platform at the University of Warwick. Sulis is funded by EPSRC Grant EP/T022108/1 and the HPC Midlands+ consortium.

PY - 2023/7/27

Y1 - 2023/7/27

N2 - We demonstrate how the many-body potential energy landscape of carbon can be explored with the nested sampling algorithm, allowing for the calculation of its pressure-temperature phase diagram. We compare four interatomic potential models: Tersoff, EDIP, GAP-20 and its recently updated version, GAP-20U. Our evaluation is focused on their macroscopic properties, melting transitions, and identifying thermodynamically stable solid structures up to at least 100 GPa. The phase diagrams of the GAP models show good agreement with experimental results. However, we find that the models’ description of graphite includes thermodynamically stable phases with incorrect layer spacing. By adding a suitable selection of structures to the database and re-training the potential, we have derived an improved model — GAP-20U+gr — that suppresses erroneous local minima in the graphitic energy landscape. At extreme high pressure nested sampling identifies two novel stable structures in the GAP-20 model, however, the stability of these is not confirmed by electronic structure calculations, highlighting routes to further extend the applicability of the GAP models.

AB - We demonstrate how the many-body potential energy landscape of carbon can be explored with the nested sampling algorithm, allowing for the calculation of its pressure-temperature phase diagram. We compare four interatomic potential models: Tersoff, EDIP, GAP-20 and its recently updated version, GAP-20U. Our evaluation is focused on their macroscopic properties, melting transitions, and identifying thermodynamically stable solid structures up to at least 100 GPa. The phase diagrams of the GAP models show good agreement with experimental results. However, we find that the models’ description of graphite includes thermodynamically stable phases with incorrect layer spacing. By adding a suitable selection of structures to the database and re-training the potential, we have derived an improved model — GAP-20U+gr — that suppresses erroneous local minima in the graphitic energy landscape. At extreme high pressure nested sampling identifies two novel stable structures in the GAP-20 model, however, the stability of these is not confirmed by electronic structure calculations, highlighting routes to further extend the applicability of the GAP models.

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Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials

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Tietoaineistot

Exploring the configuration space of elemental carbon with empirical and machine learned interatomic potentials

Projektit

NEXTCELL: Next generation interatomic potentials to simulate new cellulose based materials

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