High-performing laminated perovskite solar cells by surface engineering of perovskite films

[Display omitted] •Lamination of perovskite films by transfer printing process using hot-pressing.•Defects between perovskite films are suppressed by surface engineering.•The L-PSCs showed also superior intrinsic stability than conventional PSCs. Stacked perovskite films—laminated films in particula...

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Bibliographic Details
Published in:Applied surface science 2022-07, Vol.591, p.153148, Article 153148
Main Authors: Gong, Oh Yeong, Seo, Min Kyeong, Choi, Jin Hyuk, Kim, So-Yeon, Kim, Dong Hoe, Cho, In Sun, Park, Nam-Gyu, Han, Gill Sang, Jung, Hyun Suk
Format: Article
Language:English
Subjects:
Hot-pressing
Laminated perovskite solar cells
Lamination of perovskite film
Surface engineering
Transfer printing
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Summary:[Display omitted] •Lamination of perovskite films by transfer printing process using hot-pressing.•Defects between perovskite films are suppressed by surface engineering.•The L-PSCs showed also superior intrinsic stability than conventional PSCs. Stacked perovskite films—laminated films in particular—have garnered considerable attention owing to their excellent potential for various applications. However, perovskite solar cells fabricated using laminated perovskite films exhibit a critically low power conversion efficiency. To overcome this limitation, in this paper, we report the surface and grain boundary engineering of perovskite films via transfer printing using the hot-pressing process to attain high-performing laminated perovskite solar cells. Perovskite films whose surface and grain boundaries were selectively dissolved by acetonitrile exhibited suppressed formation of defects at the lamination interface, and uniform plastic deformation was induced in the films during the hot-pressing process. Consequently, high efficiency of 22.52% and high intrinsic stability, namely the retention of an average of 96% of the initial efficiency after 2000 h, were achieved.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2022.153148