Commercialization of lead halide perovskite-based devices is hindered by their instability towards environmental conditions. In particular, water promotes fast decomposition, leading to a drastic decrease in device performance. Integrating water-splitting active species within ancillary layers to the perovskite absorber might be a solution to this, as they could convert incoming water into oxygen and hydrogen, preserving device performance. Here, we suggest that a CuSCN nanoplatelete/p-type semiconducting polymer composite, combining hole extraction and transport properties with water oxidation activity, transforms incoming water molecules and triggers the in situ p-doping of the conjugated polymer, improving transport of photocharges. Insertion of the nanocomposite into a lead perovskite solar cell with a direct photovoltaic architecture causes stable device performance for 28 days in high-moisture conditions. Our findings demonstrate that the engineering of a hole extraction layer with possible water-splitting additives could be a viable strategy to reduce the impact of moisture in perovskite devices.

Moisture resistance in perovskite solar cells attributed to a water-splitting layer / Kim, Min; Alfano, Antonio; Perotto, Giovanni; Serri, Michele; Dengo, Nicola; Mezzetti, Alessandro; Gross, Silvia; Prato, Mirko; Salerno, Marco; Rizzo, Antonio; Sorrentino, Roberto; Cescon, Enrico; Meneghesso, Gaudenzio; DI FONZO, Fabio; Petrozza, Annamaria; Gatti, Teresa; Lamberti, Francesco. - In: COMMUNICATIONS MATERIALS. - ISSN 2662-4443. - 2:1(2021), pp. 1-12. [10.1038/s43246-020-00104-z]

Moisture resistance in perovskite solar cells attributed to a water-splitting layer

Roberto Sorrentino;Fabio Di Fonzo;Teresa Gatti;Francesco Lamberti
2021

Abstract

Commercialization of lead halide perovskite-based devices is hindered by their instability towards environmental conditions. In particular, water promotes fast decomposition, leading to a drastic decrease in device performance. Integrating water-splitting active species within ancillary layers to the perovskite absorber might be a solution to this, as they could convert incoming water into oxygen and hydrogen, preserving device performance. Here, we suggest that a CuSCN nanoplatelete/p-type semiconducting polymer composite, combining hole extraction and transport properties with water oxidation activity, transforms incoming water molecules and triggers the in situ p-doping of the conjugated polymer, improving transport of photocharges. Insertion of the nanocomposite into a lead perovskite solar cell with a direct photovoltaic architecture causes stable device performance for 28 days in high-moisture conditions. Our findings demonstrate that the engineering of a hole extraction layer with possible water-splitting additives could be a viable strategy to reduce the impact of moisture in perovskite devices.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2977474