A general-purpose machine-learning force field for bulk and nanostructured phosphorus

Volker L. Deringer; Miguel A. Caro; Gábor Csányi

doi:10.1038/s41467-020-19168-z

A general-purpose machine-learning force field for bulk and nanostructured phosphorus

Volker L. Deringer^*
, Miguel A. Caro
, Gábor Csányi

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

115 Citations (Scopus)

129 Downloads (Pure)

Abstract

Elemental phosphorus is attracting growing interest across fundamental and applied fields of research. However, atomistic simulations of phosphorus have remained an outstanding challenge. Here, we show that a universally applicable force field for phosphorus can be created by machine learning (ML) from a suitably chosen ensemble of quantum-mechanical results. Our model is fitted to density-functional theory plus many-body dispersion (DFT + MBD) data; its accuracy is demonstrated for the exfoliation of black and violet phosphorus (yielding monolayers of “phosphorene” and “hittorfene”); its transferability is shown for the transition between the molecular and network liquid phases. An application to a phosphorene nanoribbon on an experimentally relevant length scale exemplifies the power of accurate and flexible ML-driven force fields for next-generation materials modelling. The methodology promises new insights into phosphorus as well as other structurally complex, e.g., layered solids that are relevant in diverse areas of chemistry, physics, and materials science.

Original language	English
Article number	5461
Number of pages	11
Journal	Nature Communications
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41467-020-19168-z
Publication status	Published - 29 Oct 2020
MoE publication type	A1 Journal article-refereed

Funding

We thank N. Bernstein and J.R. Kermode for developing substantial parts of the potential testing framework (described in ref. 61), which we have used in the present work. V.L.D. thanks C.J. Pickard and D.M. Proserpio for ongoing valuable discussions and the Leverhulme Trust for an Early Career Fellowship. Parts of this work were carried out during V.L.D.’s previous affiliation with the University of Cambridge (until August 2019) with additional support from the Isaac Newton Trust. V.L.D. and M.A.C. acknowledge travel support from the HPC-Europa3 initiative (in the frame-work of the European Union’s Horizon 2020 research and innovation programme, Grant Agreement 730897). M.A.C. acknowledges personal funding from the Academy of Finland (grant number #310574) and computational resources from CSC—IT Center for Science. This work used the ARCHER UK National Supercomputing Service through EPSRC grant EP/P022596/1. The authors would like to acknowledge the use of the University of Oxford Advanced Research Computing (ARC) facility in carrying out this work (https://doi.org/10.5281/zenodo.22558). Post processing and visualisation of structural data was made possible by the freely available ASE91, VESTA92and OVITO93software.

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Cite this

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A general-purpose machine-learning force field for bulk and nanostructured phosphorus

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Accurate computational electrochemistry from density functional theory and multiscale

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A general-purpose machine-learning force field for bulk and nanostructured phosphorus

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GAP-20 machine learning force field for phosphorus

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Accurate computational electrochemistry from density functional theory and multiscale

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