American Chemical Society (ACS)
Journal of Physical Chemistry A
volume 124 issue 40 pages 8330-8340

Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials

Erin Antono 1
Nobuyuki N Matsuzawa 2
Julia Ling 1
James Saal 1
Hideyuki Arai 2
Masaru Sasago 2
Eiji Fujii 2
1
 
Citrine Informatics Inc., 2629 Broadway, Redwood City, California 94063, United States
2
 
Publication typeJournal Article
Publication date2020-09-17
American Chemical Society (ACS)
scimago Q2
wos Q2
SJR0.634
CiteScore4.8
Impact factor2.8
ISSN10895639, 15205215
Physical and Theoretical Chemistry
Abstract
Materials exhibiting higher mobilities than conventional organic semiconducting materials such as fullerenes and fused thiophenes are in high demand for applications such as printed electronics, organic solar cells, and image sensors. In order to discover new molecules that might show improved charge mobility, combined density functional theory (DFT) and molecular dynamics (MD) calculations were performed, guided by predictions from machine learning (ML). A ML model was constructed based on 32 values of theoretically calculated hole mobilities for thiophene derivatives, benzodifuran derivatives, a carbazole derivative and a perylene diimide derivative with the maximum value of 10-1.96 cm2/(V s). Sequential learning, also known as active learning, was applied to select compounds on which to perform DFT/MD calculation of hole mobility to simultaneously improve the mobility surrogate model and identify high mobility compounds. By performing 60 cycles of sequential learning with 165 DFT/MD calculations, a molecule having a fused thioacene structure with its calculated hole mobility of 10-1.86 cm2/(V s) was identified. This values is higher than the maximum value of mobility in the initial training data set, showing that an extrapolative discovery could be made with the sequential learning.
Found 
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Antono E. et al. Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials // Journal of Physical Chemistry A. 2020. Vol. 124. No. 40. pp. 8330-8340.
GOST all authors (up to 50) Copy
Antono E., Matsuzawa N. N., Ling J., Saal J., Arai H., Sasago M., Fujii E. Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials // Journal of Physical Chemistry A. 2020. Vol. 124. No. 40. pp. 8330-8340.
RIS |
Cite this
RIS Copy
TY - JOUR
DO - 10.1021/acs.jpca.0c05769
UR - https://doi.org/10.1021/acs.jpca.0c05769
TI - Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials
T2 - Journal of Physical Chemistry A
AU - Antono, Erin
AU - Matsuzawa, Nobuyuki N
AU - Ling, Julia
AU - Saal, James
AU - Arai, Hideyuki
AU - Sasago, Masaru
AU - Fujii, Eiji
PY - 2020
DA - 2020/09/17
PB - American Chemical Society (ACS)
SP - 8330-8340
IS - 40
VL - 124
PMID - 32940470
SN - 1089-5639
SN - 1520-5215
ER -
BibTex |
Cite this
BibTex (up to 50 authors) Copy
@article{2020_Antono,
author = {Erin Antono and Nobuyuki N Matsuzawa and Julia Ling and James Saal and Hideyuki Arai and Masaru Sasago and Eiji Fujii},
title = {Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials},
journal = {Journal of Physical Chemistry A},
year = {2020},
volume = {124},
publisher = {American Chemical Society (ACS)},
month = {sep},
url = {https://doi.org/10.1021/acs.jpca.0c05769},
number = {40},
pages = {8330--8340},
doi = {10.1021/acs.jpca.0c05769}
}
MLA
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MLA Copy
Antono, Erin, et al. “Machine-Learning Guided Quantum Chemical and Molecular Dynamics Calculations to Design Novel Hole-Conducting Organic Materials.” Journal of Physical Chemistry A, vol. 124, no. 40, Sep. 2020, pp. 8330-8340. https://doi.org/10.1021/acs.jpca.0c05769.