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2024 | OriginalPaper | Chapter

Dual-Atom Catalysts for Metal-Sulfur Batteries

Authors : Mahwash Mahar Gul, Khuram Shahzad Ahmad

Published in: Atomically Precise Electrocatalysts for Electrochemical Energy Applications

Publisher: Springer Nature Switzerland

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Abstract

Dual-atom catalysts for metal-sulfur batteries are a type of catalyst made up of two metal atoms that work together to improve the performance of metal-sulfur battery systems. These catalysts are intended to improve the electrochemical processes that take place in the battery, resulting in increased energy storage capacity and overall battery performance. The bidirectional conversion between metal and metal sulfide during charge and discharge cycles is a critical mechanism for energy storage in metal-sulfur batteries. However, this conversion process is slow, resulting in low battery efficiency and a short cycle life. Dual-atom catalysts seek to overcome these issues by enhancing reaction kinetics and offering more efficient catalytic sites. The appropriate metal pairings for dual-atom catalysts are determined by a variety of criteria, including the individual battery chemistry and the required electrochemical processes. Platinum–Nickel (Pt–Ni), iron–cobalt (Fe–Co), Palladium–Cobalt (Pd–Co), Cobalt–Tungsten (Co–W), Molybdenum phosphide (MoP) and Zinc–cobalt (Zn–Co) are examples of metal pairings utilised in dual-atom catalysts for metal-sulfur batteries. The use of dual-atom catalysts in metal-sulfur batteries has yielded encouraging results in terms of increased battery performance. However, further research is needed to optimise these catalysts, understand their underlying processes, and investigate their scalability and cost-effectiveness for actual applications in metal-sulfur battery systems.

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previous chapter Single-Atom Catalysts for Metal-Sulfur Batteries

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Title: Dual-Atom Catalysts for Metal-Sulfur Batteries
Authors: Mahwash Mahar Gul
Khuram Shahzad Ahmad
Publisher: Springer Nature Switzerland
Book: Atomically Precise Electrocatalysts for Electrochemical Energy Applications
Print ISBN: 978-3-031-54621-1

Electronic ISBN: 978-3-031-54622-8

Copyright Year: 2024
DOI: https://doi.org/10.1007/978-3-031-54622-8_22