A semiconductor-electrocatalyst nano interface constructed for successive photoelectrochemical water oxidation

Zilong Wu; Xiangyu Liu; Haijing Li; Zhiyi Sun; Maosheng Cao; Zezhou Li; Chaohe Fang; Jihan Zhou; Chuanbao Cao; Juncai Dong; Shenlong Zhao; Zhuo Chen

doi:10.1038/s41467-023-38285-z

A semiconductor-electrocatalyst nano interface constructed for successive photoelectrochemical water oxidation

Zilong Wu, Xiangyu Liu, Haijing Li, Zhiyi Sun, Maosheng Cao, Zezhou Li, Chaohe Fang, Jihan Zhou, Chuanbao Cao, Juncai Dong^*, Shenlong Zhao^*, Zhuo Chen^*

^*Corresponding author for this work

School of Material Science and Engineering

Research output: Contribution to journal › Article › peer-review

56 Citations (Scopus)

Abstract

Photoelectrochemical water splitting has long been considered an ideal approach to producing green hydrogen by utilizing solar energy. However, the limited photocurrents and large overpotentials of the anodes seriously impede large-scale application of this technology. Here, we use an interfacial engineering strategy to construct a nanostructural photoelectrochemical catalyst by incorporating a semiconductor CdS/CdSe-MoS₂ and NiFe layered double hydroxide for the oxygen evolution reaction. Impressively, the as-prepared photoelectrode requires an low potential of 1.001 V vs. reversible hydrogen electrode for a photocurrent density of 10 mA cm⁻², and this is 228 mV lower than the theoretical water splitting potential (1.229 vs. reversible hydrogen electrode). Additionally, the generated current density (15 mA cm⁻²) of the photoelectrode at a given overpotential of 0.2 V remains at 95% after long-term testing (100 h). Operando X-ray absorption spectroscopy revealed that the formation of highly oxidized Ni species under illumination provides large photocurrent gains. This finding opens an avenue for designing high-efficiency photoelectrochemical catalysts for successive water splitting.

Original language	English
Article number	2574
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-38285-z
Publication status	Published - Dec 2023

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Wu, Z., Liu, X., Li, H., Sun, Z., Cao, M., Li, Z., Fang, C., Zhou, J., Cao, C., Dong, J., Zhao, S., & Chen, Z. (2023). A semiconductor-electrocatalyst nano interface constructed for successive photoelectrochemical water oxidation. Nature Communications, 14(1), Article 2574. https://doi.org/10.1038/s41467-023-38285-z

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title = "A semiconductor-electrocatalyst nano interface constructed for successive photoelectrochemical water oxidation",

abstract = "Photoelectrochemical water splitting has long been considered an ideal approach to producing green hydrogen by utilizing solar energy. However, the limited photocurrents and large overpotentials of the anodes seriously impede large-scale application of this technology. Here, we use an interfacial engineering strategy to construct a nanostructural photoelectrochemical catalyst by incorporating a semiconductor CdS/CdSe-MoS2 and NiFe layered double hydroxide for the oxygen evolution reaction. Impressively, the as-prepared photoelectrode requires an low potential of 1.001 V vs. reversible hydrogen electrode for a photocurrent density of 10 mA cm−2, and this is 228 mV lower than the theoretical water splitting potential (1.229 vs. reversible hydrogen electrode). Additionally, the generated current density (15 mA cm−2) of the photoelectrode at a given overpotential of 0.2 V remains at 95% after long-term testing (100 h). Operando X-ray absorption spectroscopy revealed that the formation of highly oxidized Ni species under illumination provides large photocurrent gains. This finding opens an avenue for designing high-efficiency photoelectrochemical catalysts for successive water splitting.",

author = "Zilong Wu and Xiangyu Liu and Haijing Li and Zhiyi Sun and Maosheng Cao and Zezhou Li and Chaohe Fang and Jihan Zhou and Chuanbao Cao and Juncai Dong and Shenlong Zhao and Zhuo Chen",

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AU - Wu, Zilong

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AU - Sun, Zhiyi

AU - Cao, Maosheng

AU - Li, Zezhou

AU - Fang, Chaohe

AU - Zhou, Jihan

AU - Cao, Chuanbao

AU - Dong, Juncai

AU - Zhao, Shenlong

AU - Chen, Zhuo

PY - 2023/12

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N2 - Photoelectrochemical water splitting has long been considered an ideal approach to producing green hydrogen by utilizing solar energy. However, the limited photocurrents and large overpotentials of the anodes seriously impede large-scale application of this technology. Here, we use an interfacial engineering strategy to construct a nanostructural photoelectrochemical catalyst by incorporating a semiconductor CdS/CdSe-MoS2 and NiFe layered double hydroxide for the oxygen evolution reaction. Impressively, the as-prepared photoelectrode requires an low potential of 1.001 V vs. reversible hydrogen electrode for a photocurrent density of 10 mA cm−2, and this is 228 mV lower than the theoretical water splitting potential (1.229 vs. reversible hydrogen electrode). Additionally, the generated current density (15 mA cm−2) of the photoelectrode at a given overpotential of 0.2 V remains at 95% after long-term testing (100 h). Operando X-ray absorption spectroscopy revealed that the formation of highly oxidized Ni species under illumination provides large photocurrent gains. This finding opens an avenue for designing high-efficiency photoelectrochemical catalysts for successive water splitting.

AB - Photoelectrochemical water splitting has long been considered an ideal approach to producing green hydrogen by utilizing solar energy. However, the limited photocurrents and large overpotentials of the anodes seriously impede large-scale application of this technology. Here, we use an interfacial engineering strategy to construct a nanostructural photoelectrochemical catalyst by incorporating a semiconductor CdS/CdSe-MoS2 and NiFe layered double hydroxide for the oxygen evolution reaction. Impressively, the as-prepared photoelectrode requires an low potential of 1.001 V vs. reversible hydrogen electrode for a photocurrent density of 10 mA cm−2, and this is 228 mV lower than the theoretical water splitting potential (1.229 vs. reversible hydrogen electrode). Additionally, the generated current density (15 mA cm−2) of the photoelectrode at a given overpotential of 0.2 V remains at 95% after long-term testing (100 h). Operando X-ray absorption spectroscopy revealed that the formation of highly oxidized Ni species under illumination provides large photocurrent gains. This finding opens an avenue for designing high-efficiency photoelectrochemical catalysts for successive water splitting.

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A semiconductor-electrocatalyst nano interface constructed for successive photoelectrochemical water oxidation

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