JOURNAL ARTICLE
Surface Electron Affinity Modulation: Balancing Iodine Oxidation and Reduction Reaction Kinetics on Mo2C Cathode Host Catalyst toward Efficient Zn‐I2 Batteries.
Published In: Advanced Functional Materials, 2025, v. 35, n. 37. P. 1 1 of 3
Database: Academic Search Ultimate 2 of 3
Authored By: Zhang, Lei; Wang, Jie; Yang, Li; Li, Guang; Liang, Guojin; Hu, Haibo 3 of 3
Abstract
The energy efficiency of aqueous Zn‐I2 batteries (AZIBs) is traditionally enhanced by cathode host catalysts with high electron affinity, based on the consensus that stronger electron affinity improves electron‐rich polyiodides adsorption and prevents shuttle effects, thus promoting the I2/I⁻ conversion reaction. Herein, carbon‐coated Mo2C nanocrystals supported on carbon spheres (CS/Mo2C@C) as an iodine cathode catalyst is developed. Interestingly, a deviation from the expectation is observed: moderate electron affinity on CS/Mo2C@C, rather than higher on CS/Mo2C, actually leads to faster reaction kinetics, while maintaining stable adsorption of iodine species. This phenomenon can be attributed to the optimal electron‐donating properties and charge transfer dynamics associated with lower electron affinity. Through systematic electrochemical and spectroscopic analysis, it is uncovered that the conformal carbon layer covering the Mo2C nanocrystals is key to adjusting the electron‐donating capability, enhancing charge transfer, and improving interfacial reaction kinetics of the CS/Mo2C@C cathode catalyst. Consequently, the assembled AZIBs employing CS/Mo2C@C/I2 cathode demonstrate a smaller overpotential gap (0.06 V) and superior cyclic stability (89.6% capacity retention after 25 000 cycles at 5 A g⁻1) compared to the CS/Mo2C/I2 cathode (0.09 V/40.6% after 5000 cycles). This study highlights the significance of modulating surface electron affinity in cathode catalyst design for high‐efficiency AZIBs. [ABSTRACT FROM AUTHOR]
Additional Information
- Source:Advanced Functional Materials. 2025/09, Vol. 35, Issue 37, p1
- Document Type:Article
- Subject Area:Chemistry
- Publication Date:2025
- ISSN:1616-301X
- DOI:10.1002/adfm.202504281
- Accession Number:187979266
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