Title
Ion Migration-Induced Amorphization and Phase Segregation as a Degradation Mechanism in Planar Perovskite Solar Cells
Date Issued
01 July 2020
Access level
open access
Resource Type
journal article
Author(s)
Di Girolamo D.
Phung N.
Kosasih F.U.
Di Giacomo F.
Matteocci F.
Smith J.A.
Flatken M.A.
Köbler H.
Turren Cruz S.H.
Mattoni A.
Cinà L.
Latini A.
Divitini G.
Ducati C.
Di Carlo A.
Dini D.
Abate A.
Technical University Berlin
Publisher(s)
Wiley-VCH Verlag
Abstract
The operation of halide perovskite optoelectronic devices, including solar cells and LEDs, is strongly influenced by the mobility of ions comprising the crystal structure. This peculiarity is particularly true when considering the long-term stability of devices. A detailed understanding of the ion migration-driven degradation pathways is critical to design effective stabilization strategies. Nonetheless, despite substantial research in this first decade of perovskite photovoltaics, the long-term effects of ion migration remain elusive due to the complex chemistry of lead halide perovskites. By linking materials chemistry to device optoelectronics, this study highlights that electrical bias-induced perovskite amorphization and phase segregation is a crucial degradation mechanism in planar mixed halide perovskite solar cells. Depending on the biasing potential and the injected charge, halide segregation occurs, forming crystalline iodide-rich domains, which govern light emission and participate in light absorption and photocurrent generation. Additionally, the loss of crystallinity limits charge collection efficiency and eventually degrades the device performance.
Volume
10
Issue
25
Number
2000310
Language
English
OCDE Knowledge area
Ingeniería de materiales
Subjects
Scopus EID
2-s2.0-85085703272
Source
Advanced Energy Materials
ISSN of the container
16146832
Sponsor(s)
Funding text 1
D.D.G. and N.P. contributed equally to this work. The authors thank Helmholtz Zentrum Berlin (HZB) for the beamtime at together with Dr. Daniel Többens, Dr. Rahim Munir, and Hampus Näsström for their kind assistance during the beamtime. D.D.G. thanks the Ph.D. program of the University of Rome, La Sapienza. N.P. thanks the Ph.D. program of University of Potsdam. D.D.G. and N.P. thank Amran Al‐Ashouri for the support in device fabrication. F.U.K. thanks the Jardine Foundation and Cambridge Trust for a doctoral scholarship. F.U.K., G.D., and C.D. thank Tiarnan A. S. Doherty and Dr. Samuel D. Stranks (Cavendish Laboratory, University of Cambridge) for assistance in biasing devices for TEM characterization. The research leading to these results received funding from the European Union Horizon 2020 research and innovation program under grant agreement number 823717—ESTEEM3. D.D. and A.L. acknowledge the financial support from MIUR (Project PRIN 2017 with title Novel Multilayered and Micro‐Machined Electrode Nano‐Architectures for Electrocatalytic Applications—Prot. 2017YH9MRK). D.D. also acknowledges the financial support from the University of Rome, La Sapienza (Project ATENEO 2019 Prot. RM11916B756961CA). F.D.G. thanks ESPResSo project (Horizon 2020, grant 764047). S.H.T.C. thanks CONACYT‐México for support. L.C. thanks ARIADNE project (POR‐FESR 2014–2020). A.D.C. gratefully acknowledge the financial support from the Ministry of Education and Science of the Russian Federation in the framework of MegaGrant (no. 075‐15‐2019‐872 (14.Y26.31.0027/074‐02‐2018‐327)). J.A.S. thanks EPSRC and Prof. David Lidzey for Ph.D. studentship funding via CDT‐PV (EP/L01551X/1).
Funding text 2
D.D.G. and N.P. contributed equally to this work. The authors thank Helmholtz Zentrum Berlin (HZB) for the beamtime at together with Dr. Daniel Többens, Dr. Rahim Munir, and Hampus Näsström for their kind assistance during the beamtime. D.D.G. thanks the Ph.D. program of the University of Rome, La Sapienza. N.P. thanks the Ph.D. program of University of Potsdam. D.D.G. and N.P. thank Amran Al-Ashouri for the support in device fabrication. F.U.K. thanks the Jardine Foundation and Cambridge Trust for a doctoral scholarship. F.U.K., G.D., and C.D. thank Tiarnan A. S. Doherty and Dr. Samuel D. Stranks (Cavendish Laboratory, University of Cambridge) for assistance in biasing devices for TEM characterization. The research leading to these results received funding from the European Union Horizon 2020 research and innovation program under grant agreement number 823717—ESTEEM3. D.D. and A.L. acknowledge the financial support from MIUR (Project PRIN 2017 with title Novel Multilayered and Micro-Machined Electrode Nano-Architectures for Electrocatalytic Applications—Prot. 2017YH9MRK). D.D. also acknowledges the financial support from the University of Rome, La Sapienza (Project ATENEO 2019 Prot. RM11916B756961CA). F.D.G. thanks ESPResSo project (Horizon 2020, grant 764047). S.H.T.C. thanks CONACYT-México for support. L.C. thanks ARIADNE project (POR-FESR 2014–2020). A.D.C. gratefully acknowledge the financial support from the Ministry of Education and Science of the Russian Federation in the framework of MegaGrant (no. 075-15-2019-872 (14.Y26.31.0027/074-02-2018-327)). J.A.S. thanks EPSRC and Prof. David Lidzey for Ph.D. studentship funding via CDT-PV (EP/L01551X/1).
Horizon 2020 Framework Programme - H2020
Gates Cambridge Trust
Sources of information:
Directorio de Producción Científica
Scopus