High-throughput Computational Study of Halide Double Perovskite Inorganic Compounds

Yao Cai; Wei Xie; Yin Ting Teng; P. C. Harikesh; Biplab Ghosh; Patrick Huck; Kristin A. Persson; Nripan Mathews; Subodh G. Mhaisalkar; Matthew Sherburne; Mark Asta

doi:10.1021/acs.chemmater.9b00116

High-throughput Computational Study of Halide Double Perovskite Inorganic Compounds

Yao Cai^*, Wei Xie, Yin Ting Teng, P. C. Harikesh, Biplab Ghosh, Patrick Huck, Kristin A. Persson, Nripan Mathews, Subodh G. Mhaisalkar, Matthew Sherburne, Mark Asta

^*Corresponding author for this work

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

139 Citations (Scopus)

Abstract

Double perovskite halides are a class of materials with diverse chemistries that are amenable to solution-based synthesis routes, and display a range of properties for a variety of potential applications. Starting from a consideration of the octahedral and tolerance factors of ∼2000 candidate double perovskite compounds, we compute structural, electronic, and transport properties of ∼1000 using first-principles calculations based on density-functional-theory methods. The computational results have been assembled in a database that is accessible through the Materials Project online. As one potential application, double perovskites are candidates in the search for lead-free halide photovoltaic absorbers. We present the application of our database to aid the discovery of new double perovskite halide photovoltaic materials, by combining the results with optical absorption and phonon stability calculations. From three distinct classes of chemistries, 11 compounds were identified as promising solar absorbers and the complex chemical trends for band gap within each of these are analyzed, to provide guidelines for the use of substitutional alloying as a means of further tuning the electronic structure. Other possible applications of the database are also discussed.

Original language	English
Pages (from-to)	5392-5401
Number of pages	10
Journal	Chemistry of Materials
Volume	31
Issue number	15
DOIs	https://doi.org/10.1021/acs.chemmater.9b00116
Publication status	Published - Aug 13 2019
Externally published	Yes

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Publisher Copyright:
© 2019 American Chemical Society.

ASJC Scopus Subject Areas

General Chemistry
General Chemical Engineering
Materials Chemistry

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title = "High-throughput Computational Study of Halide Double Perovskite Inorganic Compounds",

abstract = "Double perovskite halides are a class of materials with diverse chemistries that are amenable to solution-based synthesis routes, and display a range of properties for a variety of potential applications. Starting from a consideration of the octahedral and tolerance factors of ∼2000 candidate double perovskite compounds, we compute structural, electronic, and transport properties of ∼1000 using first-principles calculations based on density-functional-theory methods. The computational results have been assembled in a database that is accessible through the Materials Project online. As one potential application, double perovskites are candidates in the search for lead-free halide photovoltaic absorbers. We present the application of our database to aid the discovery of new double perovskite halide photovoltaic materials, by combining the results with optical absorption and phonon stability calculations. From three distinct classes of chemistries, 11 compounds were identified as promising solar absorbers and the complex chemical trends for band gap within each of these are analyzed, to provide guidelines for the use of substitutional alloying as a means of further tuning the electronic structure. Other possible applications of the database are also discussed.",

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doi = "10.1021/acs.chemmater.9b00116",

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AU - Cai, Yao

AU - Xie, Wei

AU - Teng, Yin Ting

AU - Harikesh, P. C.

AU - Ghosh, Biplab

AU - Huck, Patrick

AU - Persson, Kristin A.

AU - Mathews, Nripan

AU - Mhaisalkar, Subodh G.

AU - Sherburne, Matthew

AU - Asta, Mark

PY - 2019/8/13

Y1 - 2019/8/13

N2 - Double perovskite halides are a class of materials with diverse chemistries that are amenable to solution-based synthesis routes, and display a range of properties for a variety of potential applications. Starting from a consideration of the octahedral and tolerance factors of ∼2000 candidate double perovskite compounds, we compute structural, electronic, and transport properties of ∼1000 using first-principles calculations based on density-functional-theory methods. The computational results have been assembled in a database that is accessible through the Materials Project online. As one potential application, double perovskites are candidates in the search for lead-free halide photovoltaic absorbers. We present the application of our database to aid the discovery of new double perovskite halide photovoltaic materials, by combining the results with optical absorption and phonon stability calculations. From three distinct classes of chemistries, 11 compounds were identified as promising solar absorbers and the complex chemical trends for band gap within each of these are analyzed, to provide guidelines for the use of substitutional alloying as a means of further tuning the electronic structure. Other possible applications of the database are also discussed.

AB - Double perovskite halides are a class of materials with diverse chemistries that are amenable to solution-based synthesis routes, and display a range of properties for a variety of potential applications. Starting from a consideration of the octahedral and tolerance factors of ∼2000 candidate double perovskite compounds, we compute structural, electronic, and transport properties of ∼1000 using first-principles calculations based on density-functional-theory methods. The computational results have been assembled in a database that is accessible through the Materials Project online. As one potential application, double perovskites are candidates in the search for lead-free halide photovoltaic absorbers. We present the application of our database to aid the discovery of new double perovskite halide photovoltaic materials, by combining the results with optical absorption and phonon stability calculations. From three distinct classes of chemistries, 11 compounds were identified as promising solar absorbers and the complex chemical trends for band gap within each of these are analyzed, to provide guidelines for the use of substitutional alloying as a means of further tuning the electronic structure. Other possible applications of the database are also discussed.

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High-throughput Computational Study of Halide Double Perovskite Inorganic Compounds

Abstract

Bibliographical note

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UN SDGs

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