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Main Authors: Baranek, Ph, Connolly, J P, Gissler, A, Schulz, Ph, Rérat, M, Dovesi, R
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.03737
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_version_ 1866917187945496576
author Baranek, Ph
Connolly, J P
Gissler, A
Schulz, Ph
Rérat, M
Dovesi, R
author_facet Baranek, Ph
Connolly, J P
Gissler, A
Schulz, Ph
Rérat, M
Dovesi, R
contents This paper presents a first step toward a pragmatic phenomenological multiscale approach to evaluate perovskite solar cell performance which determines material properties at the atomistic scale with first-principles calculations, and applies them in macro-scale device models. This work focuses on the MAPbI3 (MA = CH3NH3) perovskite and how its phase transitions impact on its optical, electronic, and structural properties which are investigated at the first-principles level. The obtained data are coupled to a numerical drift-diffusion device model enabling evaluation of the performance of corresponding single junction devices. The first-principles simulation applies a hybrid exchange-correlation functional adapted to the studied family of compounds. Validation by available experimental data is presented from materials properties to device performance, justifying the use of the approach for predictive evaluation of existing and novel perovskites. The coupling between atomistic and device models is described in terms of a framework for exchange of optical and electronic parameters between the two scales. The obtained results are systematically discussed in terms of first-principles levels of approximation performances.
format Preprint
id arxiv_https___arxiv_org_abs_2601_03737
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Impact of MAPbI3 Phase Transitions on Solar Cell Performance
Baranek, Ph
Connolly, J P
Gissler, A
Schulz, Ph
Rérat, M
Dovesi, R
Materials Science
This paper presents a first step toward a pragmatic phenomenological multiscale approach to evaluate perovskite solar cell performance which determines material properties at the atomistic scale with first-principles calculations, and applies them in macro-scale device models. This work focuses on the MAPbI3 (MA = CH3NH3) perovskite and how its phase transitions impact on its optical, electronic, and structural properties which are investigated at the first-principles level. The obtained data are coupled to a numerical drift-diffusion device model enabling evaluation of the performance of corresponding single junction devices. The first-principles simulation applies a hybrid exchange-correlation functional adapted to the studied family of compounds. Validation by available experimental data is presented from materials properties to device performance, justifying the use of the approach for predictive evaluation of existing and novel perovskites. The coupling between atomistic and device models is described in terms of a framework for exchange of optical and electronic parameters between the two scales. The obtained results are systematically discussed in terms of first-principles levels of approximation performances.
title Impact of MAPbI3 Phase Transitions on Solar Cell Performance
topic Materials Science
url https://arxiv.org/abs/2601.03737