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A General Strategy for Antimony‐Based Alloy Nanocomposite Embedded in Swiss‐Cheese‐Like Nitrogen‐Doped Porous Carbon for Energy Storage
Author(s) -
Yang Tao,
Zhong Jiasong,
Liu Jianwen,
Yuan Yongjun,
Yang Dexin,
Mao Qinan,
Li Xinyue,
Guo Zaiping
Publication year - 2021
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.202009433
Subject(s) - materials science , antimony , anode , nanocomposite , heteroatom , lithium (medication) , chemical engineering , energy storage , conductivity , pseudocapacitance , electrochemistry , carbon fibers , composite number , nanotechnology , electrode , composite material , metallurgy , supercapacitor , organic chemistry , medicine , ring (chemistry) , power (physics) , chemistry , physics , quantum mechanics , endocrinology , engineering
Abstract Due to its suitable working voltage and high theoretical storage capacity, antimony is considered a promising negative electrode material for lithium‐ion batteries (LIBs) and has attracted widespread attention. The volume effect during cycling, however, will cause the antimony anode to undergo a severe structural collapse and a rapid decrease in capacity. Here, a general in situ self‐template‐assisted strategy is proposed for the rational design and preparation of a series of MSb (M = Ni, Co, or Fe) nanocomposites with MNC coordination, which are firmly anchored on Swiss‐cheese‐like nitrogen‐doped porous carbon as anodes for LIBs. The large interface pore network structure, the introduction of heteroatoms, and the formation of strong metalNC bonds effectively enhance their electronic conductivity and structural integrity, and provide abundant interfacial lithium storage. The experimental results have proved the high rate performance and excellent cycling stability of antimony‐based composite materials. Electrochemical kinetics studies have demonstrated that the increase in capacity during cycling is mainly controlled by the diffusion mechanism rather than the pseudocapacitance contribution. This facile strategy can provide a new pathway for low‐cost and high‐yield synthesis of Sb‐based composites with high performance, and is expected to be applied in other energy‐related fields such as sodium‐/potassium‐ion batteries or electrocatalysis.

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