Orthorhombic Structures as Inorganic Halide Perovskite Models for High-Throughput DFT Investigations

Suxuen Yew; Ryan J. Morelock; Charles B. Musgrave

doi:10.1021/acs.jpcc.4c08125

Orthorhombic Structures as Inorganic Halide Perovskite Models for High-Throughput DFT Investigations

Suxuen Yew, Ryan J. Morelock, Charles B. Musgrave

Nanomaterials Theory Institute

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

Abstract

Although high-symmetry Pm-3m space group cubic models are computationally efficient for high-throughput density functional theory (DFT) calculations of inorganic ternary (ABX₃) halide perovskites (HPs), they frequently predict band gaps (E_g) that disagree with experiment. Conversely, while low-symmetry cubic polymorphous networks (PN) comprised of 160 to 320 atoms incur significantly greater computational cost, they predict E_g’s that are more closely aligned with experiment. In this study, we compare the DFT total energies and E_g’s predicted by four high-symmetry structure models (Pnma orthorhombic, R3m trigonal, P4/mbm tetragonal, and Pm-3m cubic) to cubic PNs for 5 experimentally characterized ternary HPs and find that the orthorhombic model computes E_g’s with the smallest MAD of 0.23 eV relative to the PNs. Pair distribution functions and DFT-computed total energies show that octahedral tilting, which is present in the 20-atom orthorhombic and 160-atom cubic PN models but not in the 5-atom cubic models, stabilizes all 5 compositions in our benchmarking set. We also find that imposing PN constraints when generating and optimizing these orthorhombic structures by fixing the unit cell lattice vectors and displacing the atoms prior to ionic relaxation with DFT, which we call the orthorhombic surrogate model (OSM), lowers the MAD of E_g predictions to 0.09 eV. Our OSM predicts the PN band gaps of an additional 95 theoretical inorganic ternary HPs with MAD of 0.08 eV, supporting its usage in high-throughput DFT investigations to closely estimate PN band gaps with much less computational expense.

Original language	English
Pages (from-to)	4010-4024
Number of pages	15
Journal	Journal of Physical Chemistry C
Volume	129
Issue number	8
DOIs	https://doi.org/10.1021/acs.jpcc.4c08125
State	Published - Feb 27 2025

Funding

This work is supported by the Department of Energy\u2019s Solar Energy Technologies Office (SETO) under award number DE-EE0009515 and the Hydrogen and Fuel Cell Technologies Office (HFTO) under award numbers DE-EE0008088 and DE-EE0010731. The authors acknowledge high-performance computing at the National Renewable Energy Laboratory (NREL) for providing HPC resources, including the use of the Eagle and Kestrel supercomputers that produced the results reported in this paper. The authors would also like to acknowledge members of the Zunger group, including Alex Zunger, Xingang Zhao, and Fernando Sabino for the illuminating discussions on perovskite modelling and polymorphous networks. Finally, the authors would also like to thank Zachary Bare for his feedback during the process of manuscript preparation.

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10.1021/acs.jpcc.4c08125

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title = "Orthorhombic Structures as Inorganic Halide Perovskite Models for High-Throughput DFT Investigations",

abstract = "Although high-symmetry Pm-3m space group cubic models are computationally efficient for high-throughput density functional theory (DFT) calculations of inorganic ternary (ABX3) halide perovskites (HPs), they frequently predict band gaps (Eg) that disagree with experiment. Conversely, while low-symmetry cubic polymorphous networks (PN) comprised of 160 to 320 atoms incur significantly greater computational cost, they predict Eg{\textquoteright}s that are more closely aligned with experiment. In this study, we compare the DFT total energies and Eg{\textquoteright}s predicted by four high-symmetry structure models (Pnma orthorhombic, R3m trigonal, P4/mbm tetragonal, and Pm-3m cubic) to cubic PNs for 5 experimentally characterized ternary HPs and find that the orthorhombic model computes Eg{\textquoteright}s with the smallest MAD of 0.23 eV relative to the PNs. Pair distribution functions and DFT-computed total energies show that octahedral tilting, which is present in the 20-atom orthorhombic and 160-atom cubic PN models but not in the 5-atom cubic models, stabilizes all 5 compositions in our benchmarking set. We also find that imposing PN constraints when generating and optimizing these orthorhombic structures by fixing the unit cell lattice vectors and displacing the atoms prior to ionic relaxation with DFT, which we call the orthorhombic surrogate model (OSM), lowers the MAD of Eg predictions to 0.09 eV. Our OSM predicts the PN band gaps of an additional 95 theoretical inorganic ternary HPs with MAD of 0.08 eV, supporting its usage in high-throughput DFT investigations to closely estimate PN band gaps with much less computational expense.",

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Orthorhombic Structures as Inorganic Halide Perovskite Models for High-Throughput DFT Investigations

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