Interplay of Static and Dynamic Disorder in the Mixed-Metal Chalcohalide Sn2SbS2I3

Adair Nicolson; Joachim Breternitz; Seán R. Kavanagh; Yvonne Tomm; Kazuki Morita; Michael Tovar; Aron Walsh; Susan Schorr; David O. Scanlon; Alex Squires

doi:10.1021/jacs.2c13336

Interplay of Static and Dynamic Disorder in the Mixed-Metal Chalcohalide Sn₂SbS₂I₃

Adair Nicolson, Joachim Breternitz, Seán R. Kavanagh, Yvonne Tomm, Kazuki Morita, Michael Tovar, Aron Walsh, Susan Schorr, David O. Scanlon^*, Alex Squires

^*Corresponding author for this work

Chemistry

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Abstract

Chalcohalide mixed-anion crystals have seen a rise in interest as “perovskite-inspired materials” with the goal of combining the ambient stability of metal chalcogenides with the exceptional optoelectronic performance of metal halides. Sn₂SbS₂I₃ is a promising candidate, having achieved a photovoltaic power conversion efficiency above 4%. However, there is uncertainty over the crystal structure and physical properties of this crystal family. Using a first-principles cluster expansion approach, we predict a disordered room-temperature structure, comprising both static and dynamic cation disorder on different crystallographic sites. These predictions are confirmed using single-crystal X-ray diffraction. Disorder leads to a lowering of the bandgap from 1.8 eV at low temperature to 1.5 eV at the experimental annealing temperature of 573 K. Cation disorder tailoring the bandgap allows for targeted application or for the use in a graded solar cell, which when combined with material properties associated with defect and disorder tolerance, encourages further investigation into the group IV/V chalcohalide family for optoelectronic applications.

Original language	English
Pages (from-to)	12509–12517
Number of pages	9
Journal	Journal of the American Chemical Society
Volume	145
Issue number	23
Early online date	30 May 2023
DOIs	https://doi.org/10.1021/jacs.2c13336
Publication status	Published - 14 Jun 2023

Bibliographical note

Acknowledgments:
We thank Stephan Lany and Jacob Cordell for sharing code to analyze IPR from DFT calculations. We thank Alex Ganose for a helpful discussion regarding transport properties. A.N. and S.R.K. acknowledge the EPSRC and SFI Centre for Doctoral Training in Advanced Characterisation of Materials (EP/S023259/1) for funding a Ph.D. studentship. The authors acknowledge the use of the UCL Kathleen and Thomas High Performance Computing Facility. Via membership of the UK’s HEC Materials Chemistry Consortium, which is funded by the EPSRC (EP/L000202, EP/R029431, EP/T022213), this work used the ARCHER2 UK National Supercomputing Service (www.archer2.ac.uk and the UK Materials and Molecular Modelling (MMM) Hub (Thomas – EP/P020194 and Young – EP/T022213). D.O.S. acknowledges support from the European Research Council, ERC (Grant No. 758345).

Keywords

perovskite-inspired materials
ambient stability
metal halides
optoelectronic performance
photovoltaic power conversion efficiency

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Cite this

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title = "Interplay of Static and Dynamic Disorder in the Mixed-Metal Chalcohalide Sn2SbS2I3",

abstract = "Chalcohalide mixed-anion crystals have seen a rise in interest as “perovskite-inspired materials” with the goal of combining the ambient stability of metal chalcogenides with the exceptional optoelectronic performance of metal halides. Sn2SbS2I3 is a promising candidate, having achieved a photovoltaic power conversion efficiency above 4%. However, there is uncertainty over the crystal structure and physical properties of this crystal family. Using a first-principles cluster expansion approach, we predict a disordered room-temperature structure, comprising both static and dynamic cation disorder on different crystallographic sites. These predictions are confirmed using single-crystal X-ray diffraction. Disorder leads to a lowering of the bandgap from 1.8 eV at low temperature to 1.5 eV at the experimental annealing temperature of 573 K. Cation disorder tailoring the bandgap allows for targeted application or for the use in a graded solar cell, which when combined with material properties associated with defect and disorder tolerance, encourages further investigation into the group IV/V chalcohalide family for optoelectronic applications.",

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author = "Adair Nicolson and Joachim Breternitz and Kavanagh, {Se{\'a}n R.} and Yvonne Tomm and Kazuki Morita and Michael Tovar and Aron Walsh and Susan Schorr and Scanlon, {David O.} and Alex Squires",

note = "Acknowledgments: We thank Stephan Lany and Jacob Cordell for sharing code to analyze IPR from DFT calculations. We thank Alex Ganose for a helpful discussion regarding transport properties. A.N. and S.R.K. acknowledge the EPSRC and SFI Centre for Doctoral Training in Advanced Characterisation of Materials (EP/S023259/1) for funding a Ph.D. studentship. The authors acknowledge the use of the UCL Kathleen and Thomas High Performance Computing Facility. Via membership of the UK{\textquoteright}s HEC Materials Chemistry Consortium, which is funded by the EPSRC (EP/L000202, EP/R029431, EP/T022213), this work used the ARCHER2 UK National Supercomputing Service (www.archer2.ac.uk and the UK Materials and Molecular Modelling (MMM) Hub (Thomas – EP/P020194 and Young – EP/T022213). D.O.S. acknowledges support from the European Research Council, ERC (Grant No. 758345).",

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AU - Kavanagh, Seán R.

AU - Tomm, Yvonne

AU - Morita, Kazuki

AU - Tovar, Michael

AU - Walsh, Aron

AU - Schorr, Susan

AU - Scanlon, David O.

AU - Squires, Alex

N1 - Acknowledgments: We thank Stephan Lany and Jacob Cordell for sharing code to analyze IPR from DFT calculations. We thank Alex Ganose for a helpful discussion regarding transport properties. A.N. and S.R.K. acknowledge the EPSRC and SFI Centre for Doctoral Training in Advanced Characterisation of Materials (EP/S023259/1) for funding a Ph.D. studentship. The authors acknowledge the use of the UCL Kathleen and Thomas High Performance Computing Facility. Via membership of the UK’s HEC Materials Chemistry Consortium, which is funded by the EPSRC (EP/L000202, EP/R029431, EP/T022213), this work used the ARCHER2 UK National Supercomputing Service (www.archer2.ac.uk and the UK Materials and Molecular Modelling (MMM) Hub (Thomas – EP/P020194 and Young – EP/T022213). D.O.S. acknowledges support from the European Research Council, ERC (Grant No. 758345).

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N2 - Chalcohalide mixed-anion crystals have seen a rise in interest as “perovskite-inspired materials” with the goal of combining the ambient stability of metal chalcogenides with the exceptional optoelectronic performance of metal halides. Sn2SbS2I3 is a promising candidate, having achieved a photovoltaic power conversion efficiency above 4%. However, there is uncertainty over the crystal structure and physical properties of this crystal family. Using a first-principles cluster expansion approach, we predict a disordered room-temperature structure, comprising both static and dynamic cation disorder on different crystallographic sites. These predictions are confirmed using single-crystal X-ray diffraction. Disorder leads to a lowering of the bandgap from 1.8 eV at low temperature to 1.5 eV at the experimental annealing temperature of 573 K. Cation disorder tailoring the bandgap allows for targeted application or for the use in a graded solar cell, which when combined with material properties associated with defect and disorder tolerance, encourages further investigation into the group IV/V chalcohalide family for optoelectronic applications.

AB - Chalcohalide mixed-anion crystals have seen a rise in interest as “perovskite-inspired materials” with the goal of combining the ambient stability of metal chalcogenides with the exceptional optoelectronic performance of metal halides. Sn2SbS2I3 is a promising candidate, having achieved a photovoltaic power conversion efficiency above 4%. However, there is uncertainty over the crystal structure and physical properties of this crystal family. Using a first-principles cluster expansion approach, we predict a disordered room-temperature structure, comprising both static and dynamic cation disorder on different crystallographic sites. These predictions are confirmed using single-crystal X-ray diffraction. Disorder leads to a lowering of the bandgap from 1.8 eV at low temperature to 1.5 eV at the experimental annealing temperature of 573 K. Cation disorder tailoring the bandgap allows for targeted application or for the use in a graded solar cell, which when combined with material properties associated with defect and disorder tolerance, encourages further investigation into the group IV/V chalcohalide family for optoelectronic applications.

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