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Uncovering the role of Ag in layer-alternating Ni3S2/Ag/Ni3S2 as an electrocatalyst with enhanced OER performance

It is increasingly important to develop an efficient OER catalyst that can provide high current density at low overpotentials to improve water splitting efficiency. Here, layered Ni3S2/Ag/Ni3S2(N2A1) nanosheets have been grown directly on carbon cloth via a facile alternating electrodeposition metho...

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Bibliographic Details
Published in:Inorganic chemistry frontiers 2020-10, Vol.7 (19), p.3627-3635
Main Authors: Guo, Rui, He, Yan, Wang, Renchao, You, Junhua, Lin, Hongji, Chen, Chiente, Chan, Tingshan, Liu, Xuanwen, Hu, Zhiwei
Format: Article
Language:English
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Summary:It is increasingly important to develop an efficient OER catalyst that can provide high current density at low overpotentials to improve water splitting efficiency. Here, layered Ni3S2/Ag/Ni3S2(N2A1) nanosheets have been grown directly on carbon cloth via a facile alternating electrodeposition method. Compared to the electrocatalyst Ni3S2/Ag(N1A1) with Ag as the innermost layer, the Ag/Ni3S2(A1N1) catalyst with Ni3S2 nanosheets as the initial layer takes greater advantage of the low impedance for water splitting. Benefitting from the coexistence of different morphologies of Ni3S2, quasi-three-dimensional layered N2A1 exhibits excellent catalytic activity and stability toward OER, with an overpotential of 187 mV for 10 mA·cm−2. Notably, based on the temperature-dependent measurement, the lower activation energy (Ea) of N2A1 is observed for the superior OER process. The roles of Ag in N2A1 were uncovered as affecting charge rearrangement, increasing electron transfer, and controlling morphology of Ni3S2.
ISSN:2052-1545
2052-1553
DOI:10.1039/d0qi00611d