AI Article Synopsis
- * A new electrochemical method has been developed to effectively convert metal Zn clusters into isolated single atoms, enhancing their stability.
- * The optimized SACs show a significant increase in lithium storage capacity, achieving over 300 Wh/kg after 500 cycles, highlighting their potential for energy applications.
Article Abstract
Single Atoms Catalysts (SACs) have emerged as a class of highly promising heterogeneous catalysts, where the traditional bottom-up synthesis approaches often encounter considerable challenges in relation to aggregation issues and poor stability. Consequently, achieving densely dispersed atomic species in a reliable and efficient manner remains a key focus in the field. Herein, we report a new facile electrochemical knock-down strategy for the formation of SACs, whereby the metal Zn clusters are transformed into single atoms. While a defect-rich substrate plays a pivotal role in capturing and stabilizing isolated Zn atoms, the feasibility of this novel strategy is demonstrated through a comprehensive investigation, combining experimental and theoretical studies. Furthermore, when studied in exploring for potential applications, the material prepared shows a remarkable improvement of 58.21% for the Li storage and delivers a capacity over 300 Wh kg after 500 cycles upon the transformation of Zn clusters into single atoms.
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| http://dx.doi.org/10.1021/acs.nanolett.4c00455 | DOI Listing |
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