The pursuit of stability in halide perovskites: The monovalent cation and the key for surface and bulk self-healing

D. R. Ceratti, A. V. Cohen, R. Tenne, Y. Rakita, L. Snarski, N. P. Jasti, L. Cremonesi, R. Cohen, M. Weitman, I. Rosenhek-Goldian, I. Kaplan-Ashiri, T. Bendikov, V. Kalchenko, M. Elbaum, M. A.C. Potenza, L. Kronik, G. Hodes, D. Cahen

Research output: Contribution to journalArticlepeer-review

35 Scopus citations

Abstract

We find significant differences between degradation and healing at the surface or in the bulk for each of the different APbBr3 single crystals (A = CH3NH3+, methylammonium (MA); HC(NH2)2+, formamidinium (FA); and cesium, Cs+). Using 1- and 2-photon microscopy and photobleaching we conclude that kinetics dominate the surface and thermodynamics the bulk stability. Fluorescence-lifetime imaging microscopy, as well as results from several other methods, relate the (damaged) state of the halide perovskite (HaP) after photobleaching to its modified optical and electronic properties. The A cation type strongly influences both the kinetics and the thermodynamics of recovery and degradation: FA heals best the bulk material with faster self-healing; Cs+ protects the surface best, being the least volatile of the A cations and possibly through O-passivation; MA passivates defects via methylamine from photo-dissociation, which binds to Pb2+. DFT simulations provide insight into the passivating role of MA, and also indicate the importance of the Br3- defect as well as predicts its stability. The occurrence and rate of self-healing are suggested to explain the low effective defect density in the HaPs and through this, their excellent performance. These results rationalize the use of mixed A-cation materials for optimizing both solar cell stability and overall performance of HaP-based devices, and provide a basis for designing new HaP variants.

Original languageEnglish
Pages (from-to)1570-1586
Number of pages17
JournalMaterials Horizons
Volume8
Issue number5
DOIs
StatePublished - 1 May 2021

Bibliographical note

Publisher Copyright:
© The Royal Society of Chemistry.

Funding

Supported by

FundersFunder number
European Union’s Horizon 2020 MSCA
Minerva Center for Self Repairing Systems for Energy and Sustainability
Ullmann family foundation for partial 2017– 2018
WIS’ SAERI
Weizmann Institute’s SAERI
Horizon 2020 Framework Programme764787
Minerva Foundation

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