Decoupled Water Electrolysis Driven by 1 cm 2 Single Perovskite Solar Cell Yielding a Solar-to-Hydrogen Efficiency of 14.4

Decoupled Water Electrolysis Driven by 1 cm 2 Single Perovskite Solar Cell Yielding a Solar-to-Hydrogen Efficiency of 14.4

Solar water splitting by photovoltaic (PV) electrolysis is a promising route for sustainable hydrogen production. However, multiple PV cells connected in series are generally required to fulfil the practical electrolytic voltages, which inevitably increases the system complexity and resistance. Deco...

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Veröffentlicht in:ChemSusChem 2023-01, Vol.16 (1), p.e202201689
Hauptverfasser: Lv, Fei, Qin, Zhixiao, Wu, Jiazhe, Pan, Lixia, Liu, Longjie, Chen, Yubin, Zhao, Yixin
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container_start_page e202201689
container_title ChemSusChem
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Qin, Zhixiao
Wu, Jiazhe
Pan, Lixia
Liu, Longjie
Chen, Yubin
Zhao, Yixin
description Solar water splitting by photovoltaic (PV) electrolysis is a promising route for sustainable hydrogen production. However, multiple PV cells connected in series are generally required to fulfil the practical electrolytic voltages, which inevitably increases the system complexity and resistance. Decoupled water electrolysis for separate hydrogen and oxygen evolution needs smaller voltage to drive each half-reaction, which provides a feasibility to achieve the single PV cell driven water electrolysis. Herein, by introducing sodium nickelhexacyanoferrate (NaNiHCF) as the redox mediator, decoupled acid water electrolyzer and amphoteric water electrolyzer were respectively constructed. The required voltages for the hydrogen or oxygen evolution steps matched with the output voltages of the perovskite solar cell (PSC). Impressively, by combining one 1 cm FAPbI -based PSC (efficiency: 18.77 %) with the decoupled amphoteric water electrolyzer, a solar-to-hydrogen (STH) efficiency of 14.4 % was achieved, which outperformed previously reported PSC-driven water electrolysis cells.
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title Decoupled Water Electrolysis Driven by 1 cm 2 Single Perovskite Solar Cell Yielding a Solar-to-Hydrogen Efficiency of 14.4
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