Robust Cobalt Manganese Sulfide Thin Film as an Electrocatalytic Layer for Quantum Dot-Sensitized Solar Cells with the Polysulfide Electrolyte

A quantum dot-sensitized solar cell (QDSSC) is a promising next-generation photovoltaic technology due to its clean, low cost, high efficiency, and easy fabrication. To date, various transition-metal sulfides (TMSs) have been demonstrated, yet the utilization of bimetallic sulfides has rarely been r...

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Published in	ACS sustainable chemistry & engineering Vol. 11; no. 18; pp. 6903 - 6913
Main Authors	Cheng, Yao-Sheng, Wu, Yu-Ting, Aulia, Sofiannisa, Chang, Ching-Cheng, Rinawati, Mia, Lee, Ting-Ying, Chang, Jia-Yaw, Septiani, Ni Luh Wulan, Yuliarto, Brian, Yeh, Min-Hsin
Format	Journal Article
Language	English
Published	American Chemical Society 08.05.2023
Subjects	cobalt electrodes electrolytes films (materials) fluorine green chemistry irradiation manganese solar cells sulfides tin dioxide voltammetry counter electrode polysulfide electrolyte single-step redox process cobalt manganese sulfide bimetallic quantum dot-sensitized solar cells
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Abstract	A quantum dot-sensitized solar cell (QDSSC) is a promising next-generation photovoltaic technology due to its clean, low cost, high efficiency, and easy fabrication. To date, various transition-metal sulfides (TMSs) have been demonstrated, yet the utilization of bimetallic sulfides has rarely been reported. While the bimetallic TMS has excellent chemical and physical properties, it displayed improved activity and stability as a counter electrode (CE) in QDSSCs with polysulfide electrolytes. In this regard, a simple yet affordable method is developed for manufacturing CEs based on cobalt manganese sulfide (CMS) composites. Herein, cobalt manganese oxyhydroxide was first deposited on the fluorine tin oxide substrate by a single-step redox process and then sulfurized to CMS. By controlling the precursor ratio of Co and Mn, the bimetallic CMS could be adjusted to manipulate the S n 2– reduction activity. Taking the advantage of those bimetallic systems, their synergistic effects demonstrated superior long-term stability in a different multi-cyclic voltammetry treatment than conventional CuS CEs. Notably, the QDSSCs with optimized CMS CEs also exhibited a high solar-to-electricity conversion efficiency (η) of 5.88 ± 0.19% under 100 mW cm–2 irradiation, indicating that CMS CE exhibited superior reduction activity to S n 2–.
AbstractList	A quantum dot-sensitized solar cell (QDSSC) is a promising next-generation photovoltaic technology due to its clean, low cost, high efficiency, and easy fabrication. To date, various transition-metal sulfides (TMSs) have been demonstrated, yet the utilization of bimetallic sulfides has rarely been reported. While the bimetallic TMS has excellent chemical and physical properties, it displayed improved activity and stability as a counter electrode (CE) in QDSSCs with polysulfide electrolytes. In this regard, a simple yet affordable method is developed for manufacturing CEs based on cobalt manganese sulfide (CMS) composites. Herein, cobalt manganese oxyhydroxide was first deposited on the fluorine tin oxide substrate by a single-step redox process and then sulfurized to CMS. By controlling the precursor ratio of Co and Mn, the bimetallic CMS could be adjusted to manipulate the Sₙ ²– reduction activity. Taking the advantage of those bimetallic systems, their synergistic effects demonstrated superior long-term stability in a different multi-cyclic voltammetry treatment than conventional CuS CEs. Notably, the QDSSCs with optimized CMS CEs also exhibited a high solar-to-electricity conversion efficiency (η) of 5.88 ± 0.19% under 100 mW cm–² irradiation, indicating that CMS CE exhibited superior reduction activity to Sₙ ²–. A quantum dot-sensitized solar cell (QDSSC) is a promising next-generation photovoltaic technology due to its clean, low cost, high efficiency, and easy fabrication. To date, various transition-metal sulfides (TMSs) have been demonstrated, yet the utilization of bimetallic sulfides has rarely been reported. While the bimetallic TMS has excellent chemical and physical properties, it displayed improved activity and stability as a counter electrode (CE) in QDSSCs with polysulfide electrolytes. In this regard, a simple yet affordable method is developed for manufacturing CEs based on cobalt manganese sulfide (CMS) composites. Herein, cobalt manganese oxyhydroxide was first deposited on the fluorine tin oxide substrate by a single-step redox process and then sulfurized to CMS. By controlling the precursor ratio of Co and Mn, the bimetallic CMS could be adjusted to manipulate the S n 2– reduction activity. Taking the advantage of those bimetallic systems, their synergistic effects demonstrated superior long-term stability in a different multi-cyclic voltammetry treatment than conventional CuS CEs. Notably, the QDSSCs with optimized CMS CEs also exhibited a high solar-to-electricity conversion efficiency (η) of 5.88 ± 0.19% under 100 mW cm–2 irradiation, indicating that CMS CE exhibited superior reduction activity to S n 2–.
Author	Rinawati, Mia Chang, Ching-Cheng Yuliarto, Brian Cheng, Yao-Sheng Wu, Yu-Ting Yeh, Min-Hsin Lee, Ting-Ying Aulia, Sofiannisa Septiani, Ni Luh Wulan Chang, Jia-Yaw
AuthorAffiliation	Advanced Functional Materials Laboratory, Department of Engineering Physics Department of Chemical Engineering Institute of Technology Bandung (ITB)
AuthorAffiliation_xml	– name: Advanced Functional Materials Laboratory, Department of Engineering Physics – name: Department of Chemical Engineering – name: Institute of Technology Bandung (ITB)
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SubjectTerms	cobalt electrodes electrolytes films (materials) fluorine green chemistry irradiation manganese solar cells sulfides tin dioxide voltammetry
Title	Robust Cobalt Manganese Sulfide Thin Film as an Electrocatalytic Layer for Quantum Dot-Sensitized Solar Cells with the Polysulfide Electrolyte
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