用于锌碘电池的非晶态CoP@C主体材料对碘物种的增强吸附-催化转化

Enhanced Adsorption-Catalytic Conversion of Iodine Species by Amorphous CoP@C Host Materials for Zinc Iodine Battery.

作者信息

Fu Yang, Zhu Lingfeng, Zheng Xiaorui, Fan Hua, Wang Shiwen, Li Hui, Ma Tianyi

机构信息

Centre for Atomaterials and Nanomanufacturing (CAN), School of Science, RMIT University, Melbourne, Victoria 3000, Australia.

ARC Industrial Transformation Research Hub for Intelligent Energy Efficiency in Future Protected Cropping (E2Crop), Melbourne, Victoria 3000, Australia.

出版信息

Chem Bio Eng. 2025 Mar 13;2(6):341-349. doi: 10.1021/cbe.4c00176. eCollection 2025 Jun 26.

DOI:10.1021/cbe.4c00176

PMID:40599350

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12207277/

Abstract

Extensive applications of aqueous zinc iodine batteries (AZIBs) are hindered by the sluggish iodine redox reaction and shuttling effect of the polyiodides. In this study, amorphous cobalt phosphide grown on activated carbon (ACoP@C) was proposed as an iodine host material to address these issues. Specifically, the ACoP@C can offer numerous iodine anchoring sites and proposed electrocatalytic properties, which significantly reduce shuttling and enhance the conversion kinetics of iodine species. Additionally, the conductive carbon substrate with abundant porous channels facilitates rapid and continuous long-range electron and ion transport. As a result, the ACoP@C/I cathode demonstrated high capacities of 173.7 mA h g at 0.1 A g and 99.0 mA h g at 5.0 A g, along with a stable long cycle capacity of 80.0 mA h g over 850 cycles at 1.0 A g. Moreover, UV spectroscopy and electrochemical measurements revealed enhanced redox mechanisms of the iodine species. This study provides valuable insights for the design and development of efficient amorphous catalyst materials for future AZIBs.

摘要

水系锌碘电池（AZIBs）的广泛应用受到碘氧化还原反应缓慢和多碘化物穿梭效应的阻碍。在本研究中，提出了一种生长在活性炭上的非晶态磷化钴（ACoP@C）作为碘主体材料来解决这些问题。具体而言，ACoP@C可以提供大量的碘锚定位点并具有所提出的电催化性能，这显著减少了穿梭效应并增强了碘物种的转化动力学。此外，具有丰富多孔通道的导电碳基底有助于快速且连续的长程电子和离子传输。结果，ACoP@C/I阴极在0.1 A g时表现出173.7 mA h g的高容量，在5.0 A g时表现出99.0 mA h g的高容量，并且在1.0 A g下850次循环中具有80.0 mA h g的稳定长循环容量。此外，紫外光谱和电化学测量揭示了碘物种增强的氧化还原机制。本研究为未来AZIBs高效非晶态催化剂材料的设计和开发提供了有价值的见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d94b/12207277/5d3297a2164b/be4c00176_0001.jpg

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用于锌碘电池的非晶态CoP@C主体材料对碘物种的增强吸附-催化转化

Enhanced Adsorption-Catalytic Conversion of Iodine Species by Amorphous CoP@C Host Materials for Zinc Iodine Battery.

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