Spin-induced electron transfer simultaneously enhances the intrinsic activity and stability of amorphous MoSx-based materials toward efficient hydrogen evolution

Abstract

Designing MoSx-based materials to simultaneously realize high intrinsic activity and reliable stability remains quite challenging since there is a contradictory relationship between them. For example, high intrinsic activity or efficient charge transfer indicates that the MoSx-based materials can provide abundant electron-rich sulfur atoms for the hydrogen evolution reaction (HER); a lot of H+ will attack these sulfur atoms; thus, this results in the massive missing of sulfur atoms and poor electrochemical stability. Instead, electron-deficient sulfur atoms lead to an unsatisfactory HER activity regardless of high stability. Herein, a feasible strategy for spin-state regulation is proposed to promote charge transfer, strengthen the Mo–S bond and activate sulfur atoms of MoSx toward efficient HER. In our strategy, the spin transition of the Co-doped species increases the unpaired electrons, favors wide spin channels and accelerates localized electron transfer; additionally, Co-doping decreases the band-gap of the electrocatalyst. These factors collectively improve charge transfer during the HER. Second, the spin- and electronegativity-induced electron redistribution decreases the Mo–S bond length, which efficiently inhibits the massive missing of bridging or apical sulfur atoms. Third, introducing Co species into [Mo3S13]2− nanoclusters activates the terminal sulfur atoms owing to reasonable charge accumulation to favor the absorption of H*. With these benefits, the optimized electrocatalyst demonstrates high intrinsic activity and reliable stability. Our work provides a feasible strategy to design and synthesize the outstanding MoSx-based materials from the spin effect and presents an insightful understanding of the possible mechanism about hydrogen spillover as well as enhancing their durability and structural stability toward efficient electrocatalysis.

Graphical abstract: Spin-induced electron transfer simultaneously enhances the intrinsic activity and stability of amorphous MoSx-based materials toward efficient hydrogen evolution

Supplementary files

Article information

Article type
Paper
Submitted
09 Jul 2024
Accepted
29 Sep 2024
First published
01 Oct 2024

J. Mater. Chem. A, 2024, Advance Article

Spin-induced electron transfer simultaneously enhances the intrinsic activity and stability of amorphous MoSx-based materials toward efficient hydrogen evolution

R. Li, Y. Guo, X. Yang, Z. Liu, X. Li, Y. Li, Y. Huang, J. Liu, S. Yu, M. Sun, L. Chen, B. Su and Y. Wang, J. Mater. Chem. A, 2024, Advance Article , DOI: 10.1039/D4TA04756G

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