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Machine learning for the structure–energy–property landscapes of molecular crystals

Machine learning for the structure–energy–property landscapes of molecular crystals
Machine learning for the structure–energy–property landscapes of molecular crystals
Molecular crystals play an important role in several fields of science and technology. They frequently crystallize in different polymorphs with substantially different physical properties. To help guide the synthesis of candidate materials, atomic-scale modelling can be used to enumerate the stable polymorphs and to predict their properties, as well as to propose heuristic rules to rationalize the correlations between crystal structure and materials properties. Here we show how a recently-developed machine-learning (ML) framework can be used to achieve inexpensive and accurate predictions of the stability and properties of polymorphs, and a data-driven classification that is less biased and more flexible than typical heuristic rules. We discuss, as examples, the lattice energy and property landscapes of pentacene and two azapentacene isomers that are of interest as organic semiconductor materials. We show that we can estimate force field or DFT lattice energies with sub-kJ/mol accuracy, using only a few hundred reference configurations, and reduce by a factor of ten the computational effort needed to predict charge mobility in the crystal structures. The automatic structural classification of the polymorphs reveals a more detailed picture of molecular packing than that provided by conventional heuristics, and helps disentangling the role of hydrogen bonded and $\pi$-stacking interactions in determining molecular self-assembly. This observation demonstrates that ML is not just a black-box scheme to interpolate between reference calculations, but can also be used as a tool to gain intuitive insights into structure-property relations in molecular crystal engineering.
1478-6524
1289-1300
Musil, Felix
19b51679-7518-4a2f-bebc-77693fb87628
De, Sandip
bdfd8eaf-bfbf-4d3c-8a39-1e412b5617c0
Yang, Jack
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Campbell, Joshua E.
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Day, Graeme M.
e3be79ba-ad12-4461-b735-74d5c4355636
Ceriotti, Michele
b69d9c3a-d8f2-4943-87f8-91a598594dfe
Musil, Felix
19b51679-7518-4a2f-bebc-77693fb87628
De, Sandip
bdfd8eaf-bfbf-4d3c-8a39-1e412b5617c0
Yang, Jack
4f29196a-5127-4511-8dba-4aea32a4e25e
Campbell, Joshua E.
a4dc584e-5bf6-432f-8b3e-e2ba4e67015b
Day, Graeme M.
e3be79ba-ad12-4461-b735-74d5c4355636
Ceriotti, Michele
b69d9c3a-d8f2-4943-87f8-91a598594dfe

Musil, Felix, De, Sandip, Yang, Jack, Campbell, Joshua E., Day, Graeme M. and Ceriotti, Michele (2018) Machine learning for the structure–energy–property landscapes of molecular crystals. Chemical Science, 9 (5), 1289-1300. (doi:10.1039/C7SC04665K).

Record type: Article

Abstract

Molecular crystals play an important role in several fields of science and technology. They frequently crystallize in different polymorphs with substantially different physical properties. To help guide the synthesis of candidate materials, atomic-scale modelling can be used to enumerate the stable polymorphs and to predict their properties, as well as to propose heuristic rules to rationalize the correlations between crystal structure and materials properties. Here we show how a recently-developed machine-learning (ML) framework can be used to achieve inexpensive and accurate predictions of the stability and properties of polymorphs, and a data-driven classification that is less biased and more flexible than typical heuristic rules. We discuss, as examples, the lattice energy and property landscapes of pentacene and two azapentacene isomers that are of interest as organic semiconductor materials. We show that we can estimate force field or DFT lattice energies with sub-kJ/mol accuracy, using only a few hundred reference configurations, and reduce by a factor of ten the computational effort needed to predict charge mobility in the crystal structures. The automatic structural classification of the polymorphs reveals a more detailed picture of molecular packing than that provided by conventional heuristics, and helps disentangling the role of hydrogen bonded and $\pi$-stacking interactions in determining molecular self-assembly. This observation demonstrates that ML is not just a black-box scheme to interpolate between reference calculations, but can also be used as a tool to gain intuitive insights into structure-property relations in molecular crystal engineering.

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Molecular_Crystals___Classification_and_Properties (21) - Accepted Manuscript
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More information

Accepted/In Press date: 11 December 2017
e-pub ahead of print date: 12 December 2017
Published date: 7 February 2018

Identifiers

Local EPrints ID: 416533
URI: http://eprints.soton.ac.uk/id/eprint/416533
ISSN: 1478-6524
PURE UUID: a5a92b55-a257-4c81-a9a3-6db763690ea4
ORCID for Jack Yang: ORCID iD orcid.org/0000-0003-3589-6807
ORCID for Graeme M. Day: ORCID iD orcid.org/0000-0001-8396-2771

Catalogue record

Date deposited: 21 Dec 2017 17:30
Last modified: 16 Mar 2024 06:02

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Contributors

Author: Felix Musil
Author: Sandip De
Author: Jack Yang ORCID iD
Author: Joshua E. Campbell
Author: Graeme M. Day ORCID iD
Author: Michele Ceriotti

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