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JOURNAL ARTICLE

Atom‐Level 2D Catalysts Accelerating Deposition/Dissolution Kinetics in Lithium–Sulfur Batteries

Kaipeng ChengXiahui HuangYuting LiJianbo ZhaoLidong SunYinghuan XuZhenjiang CaoYahong Chen

Year: 2024 Journal:   Advanced Functional Materials Vol: 35 (1)   Publisher: Wiley
DOI: 10.1002/adfm.202410742
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Abstract

Abstract The performance of high‐energy‐density lithium–sulfur (Li–S) batteries is limited by the unmanageable deposition/dissolution kinetics of lithium anode and sulfur cathode, leading to subpar electrochemical efficiency. Prior to being deposited on the electrolyte/electrode interface or within the interior, the solvated lithium‐ion (Li + ) must undergo de‐solvation to produce free Li + ions. These ions then participate in subsequent Redox reactions. The sulfur cathode faces challenges related to solid–liquid transformation and polysulfide conversion/shuttle, which impact the deposition/dissolution process. These issues collectively create insurmountable electrochemical barriers in lithium–sulfur batteries. Atom‐level 2D catalysts, contributing to the consummate atomic efficiency (≈100 at%), play an important role in accelerating deposition/dissolution kinetics in lithium–sulfur batteries. In the review, the preparation of atom‐level 2D catalysts and catalytic kinetic process on accelerating Li + de‐solvation, Li 0 stripping/dissolution, Li 0 nucleation/deposition of lithium anode, polysulfide conversion, and Li x S deposition of sulfur cathode are summarized, and the outlook of high‐performance single‐atom, multiple atoms modified 2D catalysts in lithium, sodium, and zinc‐based batteries is putting forward.

Keywords:
Materials science Dissolution Kinetics Catalysis Lithium (medication) Atom (system on chip) Sulfur Deposition (geology) Chemical engineering Inorganic chemistry Metallurgy Organic chemistry Chemistry

Metrics

9
Cited By
3.32
FWCI (Field Weighted Citation Impact)
165
Refs
0.89
Citation Normalized Percentile
Is in top 1%
Is in top 10%

Citation History

Topics

Advanced Battery Materials and Technologies
Physical Sciences →  Engineering →  Electrical and Electronic Engineering
Advancements in Battery Materials
Physical Sciences →  Engineering →  Electrical and Electronic Engineering
MXene and MAX Phase Materials
Physical Sciences →  Materials Science →  Materials Chemistry

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