Photoprotection in metal halide perovskites by ionic defect formation

Nga Phung; Alessandro Mattoni; Joel A. Smith; Dieter Skroblin; Hans Köbler; Leo Choubrac; Joachim Breternitz; Jinzhao Li; Thomas Unold; Susan Schorr; Christian Gollwitzer; Ivan G. Scheblykin; Eva L. Unger; Michael Saliba; Simone Meloni; Antonio Abate; Aboma Merdasa

doi:10.1016/j.joule.2022.06.029

Photoprotection in metal halide perovskites by ionic defect formation

Nga Phung, Alessandro Mattoni, Joel A. Smith, Dieter Skroblin, Hans Köbler, Leo Choubrac, Joachim Breternitz, Jinzhao Li, Thomas Unold, Susan Schorr, Christian Gollwitzer, Ivan G. Scheblykin, Eva L. Unger, Michael Saliba, Simone Meloni, Antonio Abate, Aboma Merdasa

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

Abstract

Photostability is critical for long-term solar cell operation. While light-triggered defects are usually reported as evidence of material degradation, we reveal that the formation of certain defects in metal halide perovskites is crucial for protection against intense or prolonged light exposure. We identify an inherent self-regulating cycle of formation and recovery of ionic defects under light exposure that mitigates the overheating of the lattice due to hot carrier cooling, which allows exposure to several thousand suns without degrading. The excess energy instead dissipates by forming defects, which in turn alters the optoelectronic properties of the absorber, resulting in a temporary reduction of photon absorption. Defects gradually recover to restore the original optoelectronic properties of the absorber. Photoprotection is a key feature for the photostability in plants. Thus, finding a protection mechanism in metal halide perovskites similar to those in nature is encouraging for the development of long-term sustainable solar cells.

Original language	English
Pages (from-to)	2152-2174
Number of pages	23
Journal	Joule
Volume	6
Issue number	9
DOIs	https://doi.org/10.1016/j.joule.2022.06.029
Publication status	Published - 2022 Sept 21

Subject classification (UKÄ)

Physical Chemistry (including Surface- and Colloid Chemistry)

Free keywords

concentration PV
defect chemistry
defect recovery
density functional theory
halide perovskite
molecular dynamic simulation
photoluminescence
photoprotection
photostability
thermal imaging

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10.1016/j.joule.2022.06.029Licence: CC BY

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Phung, N., Mattoni, A., Smith, J. A., Skroblin, D., Köbler, H., Choubrac, L., Breternitz, J., Li, J., Unold, T., Schorr, S., Gollwitzer, C., Scheblykin, I. G., Unger, E. L., Saliba, M., Meloni, S., Abate, A., & Merdasa, A. (2022). Photoprotection in metal halide perovskites by ionic defect formation. Joule, 6(9), 2152-2174. https://doi.org/10.1016/j.joule.2022.06.029

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title = "Photoprotection in metal halide perovskites by ionic defect formation",

abstract = "Photostability is critical for long-term solar cell operation. While light-triggered defects are usually reported as evidence of material degradation, we reveal that the formation of certain defects in metal halide perovskites is crucial for protection against intense or prolonged light exposure. We identify an inherent self-regulating cycle of formation and recovery of ionic defects under light exposure that mitigates the overheating of the lattice due to hot carrier cooling, which allows exposure to several thousand suns without degrading. The excess energy instead dissipates by forming defects, which in turn alters the optoelectronic properties of the absorber, resulting in a temporary reduction of photon absorption. Defects gradually recover to restore the original optoelectronic properties of the absorber. Photoprotection is a key feature for the photostability in plants. Thus, finding a protection mechanism in metal halide perovskites similar to those in nature is encouraging for the development of long-term sustainable solar cells.",

keywords = "concentration PV, defect chemistry, defect recovery, density functional theory, halide perovskite, molecular dynamic simulation, photoluminescence, photoprotection, photostability, thermal imaging",

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doi = "10.1016/j.joule.2022.06.029",

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T1 - Photoprotection in metal halide perovskites by ionic defect formation

AU - Phung, Nga

AU - Mattoni, Alessandro

AU - Smith, Joel A.

AU - Skroblin, Dieter

AU - Köbler, Hans

AU - Choubrac, Leo

AU - Breternitz, Joachim

AU - Li, Jinzhao

AU - Unold, Thomas

AU - Schorr, Susan

AU - Gollwitzer, Christian

AU - Scheblykin, Ivan G.

AU - Unger, Eva L.

AU - Saliba, Michael

AU - Meloni, Simone

AU - Abate, Antonio

AU - Merdasa, Aboma

PY - 2022/9/21

Y1 - 2022/9/21

N2 - Photostability is critical for long-term solar cell operation. While light-triggered defects are usually reported as evidence of material degradation, we reveal that the formation of certain defects in metal halide perovskites is crucial for protection against intense or prolonged light exposure. We identify an inherent self-regulating cycle of formation and recovery of ionic defects under light exposure that mitigates the overheating of the lattice due to hot carrier cooling, which allows exposure to several thousand suns without degrading. The excess energy instead dissipates by forming defects, which in turn alters the optoelectronic properties of the absorber, resulting in a temporary reduction of photon absorption. Defects gradually recover to restore the original optoelectronic properties of the absorber. Photoprotection is a key feature for the photostability in plants. Thus, finding a protection mechanism in metal halide perovskites similar to those in nature is encouraging for the development of long-term sustainable solar cells.

AB - Photostability is critical for long-term solar cell operation. While light-triggered defects are usually reported as evidence of material degradation, we reveal that the formation of certain defects in metal halide perovskites is crucial for protection against intense or prolonged light exposure. We identify an inherent self-regulating cycle of formation and recovery of ionic defects under light exposure that mitigates the overheating of the lattice due to hot carrier cooling, which allows exposure to several thousand suns without degrading. The excess energy instead dissipates by forming defects, which in turn alters the optoelectronic properties of the absorber, resulting in a temporary reduction of photon absorption. Defects gradually recover to restore the original optoelectronic properties of the absorber. Photoprotection is a key feature for the photostability in plants. Thus, finding a protection mechanism in metal halide perovskites similar to those in nature is encouraging for the development of long-term sustainable solar cells.

KW - concentration PV

KW - defect chemistry

KW - defect recovery

KW - density functional theory

KW - halide perovskite

KW - molecular dynamic simulation

KW - photoluminescence

KW - photoprotection

KW - photostability

KW - thermal imaging

UR - https://www.scopus.com/pages/publications/85136747050

U2 - 10.1016/j.joule.2022.06.029

DO - 10.1016/j.joule.2022.06.029

M3 - Article

AN - SCOPUS:85136747050

SN - 2542-4351

VL - 6

SP - 2152

EP - 2174

JO - Joule

JF - Joule

IS - 9

ER -

Photoprotection in metal halide perovskites by ionic defect formation

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