TY - JOUR
T1 - Learn-and-Match Molecular Cations for Perovskites
AU - Park, Heesoo
AU - Mall, Raghvendra
AU - Alharbi, Fahhad H.
AU - Sanvito, Stefano
AU - Tabet, Nouar
AU - Bensmail, Halima
AU - El-Mellouhi, Fedwa
N1 - Publisher Copyright:
© 2019 American Chemical Society.
PY - 2019/8/22
Y1 - 2019/8/22
N2 - Forecasting the structural stability of hybrid organic/inorganic compounds, where polyatomic molecules replace atoms, is a challenging task; the composition space is vast, and the reference structure for the organic molecules is ambiguously defined. In this work, we use a range of machine-learning algorithms, constructed from state-of-the-art density functional theory data, to conduct a systematic analysis on the likelihood of a given cation to be housed in the perovskite structure. In particular, we consider both ABC3 chalcogenide (I-V-VI3) and halide (I-II-VII3) perovskites. We find that the effective atomic radius and the number of lone pairs residing on the A-site cation are sufficient features to describe the perovskite phase stability. Thus, the presented machine-learning approach provides an efficient way to map the phase stability of the vast class of compounds, including situations where a cation mixture replaces a single A-site cation. This work demonstrates that advanced electronic structure theory combined with machine-learning analysis can provide an efficient strategy superior to the conventional trial-and-error approach in materials design.
AB - Forecasting the structural stability of hybrid organic/inorganic compounds, where polyatomic molecules replace atoms, is a challenging task; the composition space is vast, and the reference structure for the organic molecules is ambiguously defined. In this work, we use a range of machine-learning algorithms, constructed from state-of-the-art density functional theory data, to conduct a systematic analysis on the likelihood of a given cation to be housed in the perovskite structure. In particular, we consider both ABC3 chalcogenide (I-V-VI3) and halide (I-II-VII3) perovskites. We find that the effective atomic radius and the number of lone pairs residing on the A-site cation are sufficient features to describe the perovskite phase stability. Thus, the presented machine-learning approach provides an efficient way to map the phase stability of the vast class of compounds, including situations where a cation mixture replaces a single A-site cation. This work demonstrates that advanced electronic structure theory combined with machine-learning analysis can provide an efficient strategy superior to the conventional trial-and-error approach in materials design.
UR - http://www.scopus.com/inward/record.url?scp=85070896040&partnerID=8YFLogxK
U2 - 10.1021/acs.jpca.9b06208
DO - 10.1021/acs.jpca.9b06208
M3 - Article
C2 - 31343887
AN - SCOPUS:85070896040
SN - 1089-5639
VL - 123
SP - 7323
EP - 7334
JO - Journal of Physical Chemistry A
JF - Journal of Physical Chemistry A
IS - 33
ER -