Distinguishing Models for Mixed Halide Lead Perovskite Photosegregation via Terminal Halide Stoichiometry

Photoinduced halide segregation in mixed halide hybrid perovskites [i.e., APb(I1– xBrx)3] represents an intrinsic instability that impedes their commercialization. Resolving this issue requires developing a microscopic understanding of the phenomenon. Key to this is distinguishing existing models o...

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Veröffentlicht in:	ACS energy letters 2021-06, Vol.6 (6), p.2064-2071
Hauptverfasser:	Pavlovetc, Ilia M, Ruth, Anthony, Gushchina, Irina, Ngo, Loc, Zhang, Shubin, Zhang, Zhuoming, Kuno, Masaru
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Schlagworte:	Chemistry Electrochemistry Energy & Fuels Materials Science Science & Technology - Other Topics
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container_end_page	2071
container_issue	6
container_start_page	2064
container_title	ACS energy letters
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creator	Pavlovetc, Ilia M Ruth, Anthony Gushchina, Irina Ngo, Loc Zhang, Shubin Zhang, Zhuoming Kuno, Masaru
description	Photoinduced halide segregation in mixed halide hybrid perovskites [i.e., APb(I1– xBrx)3] represents an intrinsic instability that impedes their commercialization. Resolving this issue requires developing a microscopic understanding of the phenomenon. Key to this is distinguishing existing models of halide photosegregation by comparing their corresponding predictions to experiment. Here, we test the temperature dependency of predicted perovskite terminal stoichiometries (x terminal), following photosegregation, in single and double cation mixed halide perovskites. Our results show a general temperature invariance of x terminal. This largely supports the idea that band gap difference between parent and halide-segregated perovskite phases drives photosegregation. Beyond this, careful examination of temperature- and halide composition-dependent emission energies suggests an alternative explanation for the enhanced photostability of mixed cation/mixed halide perovskites, linked to band gap energy differences between parent and phase-segregated perovskite phases. Together, our results make inroads in clarifying the microscopic origin of mixed halide perovskite photosegregation and pave the way toward approaches that stabilize their use in applications.
doi_str_mv	10.1021/acsenergylett.1c00790
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title	Distinguishing Models for Mixed Halide Lead Perovskite Photosegregation via Terminal Halide Stoichiometry
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