Organic–Rare Earth Hybrid Anode with Superior Cyclability for Lithium Ion Battery

Jianwei Wang; Xiaolei Sun; Lingling Xu; Jiale Xia; Yaodong Yang; Zongyou Yin; Feng Luo; Yaping Du

doi:10.1002/admi.201902168

Organic–Rare Earth Hybrid Anode with Superior Cyclability for Lithium Ion Battery

Jianwei Wang, Xiaolei Sun, Lingling Xu, Jiale Xia, Yaodong Yang, Zongyou Yin^*, Feng Luo, Yaping Du

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

21 Citations (Scopus)

Abstract

Organic compounds with electroactive sites are considered as a new generation of green electrode materials for lithium ion batteries. However, exploring effective approaches to design high-capacity molecules and suppressing their solubilization remain big challenges. Herein, a functional anode architecture is first designed by using chemical bonds between organic compound and rare earth hollow structure, which enables active materials to be efficiently utilized, accelerates reaction kinetics, and mitigates undesired dissolution in electrolyte. Compared with pure organic sodium naphthyl-based tetrathiocarboxylate (SNBT) compound and CeO₂@Carbon, the hybrid electrode (CeO₂@Carbon/SNBT) exhibits the best long-term cyclability and its capacity retention has significantly increased. The current strategy would trigger more investigations into the development of organic materials for commercialized applications.

Original language	English
Article number	1902168
Journal	Advanced Materials Interfaces
Volume	7
Issue number	9
DOIs	https://doi.org/10.1002/admi.201902168
Publication status	Published - 1 May 2020

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abstract = "Organic compounds with electroactive sites are considered as a new generation of green electrode materials for lithium ion batteries. However, exploring effective approaches to design high-capacity molecules and suppressing their solubilization remain big challenges. Herein, a functional anode architecture is first designed by using chemical bonds between organic compound and rare earth hollow structure, which enables active materials to be efficiently utilized, accelerates reaction kinetics, and mitigates undesired dissolution in electrolyte. Compared with pure organic sodium naphthyl-based tetrathiocarboxylate (SNBT) compound and CeO2@Carbon, the hybrid electrode (CeO2@Carbon/SNBT) exhibits the best long-term cyclability and its capacity retention has significantly increased. The current strategy would trigger more investigations into the development of organic materials for commercialized applications.",

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AU - Wang, Jianwei

AU - Sun, Xiaolei

AU - Xu, Lingling

AU - Xia, Jiale

AU - Yang, Yaodong

AU - Yin, Zongyou

AU - Luo, Feng

AU - Du, Yaping

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AB - Organic compounds with electroactive sites are considered as a new generation of green electrode materials for lithium ion batteries. However, exploring effective approaches to design high-capacity molecules and suppressing their solubilization remain big challenges. Herein, a functional anode architecture is first designed by using chemical bonds between organic compound and rare earth hollow structure, which enables active materials to be efficiently utilized, accelerates reaction kinetics, and mitigates undesired dissolution in electrolyte. Compared with pure organic sodium naphthyl-based tetrathiocarboxylate (SNBT) compound and CeO2@Carbon, the hybrid electrode (CeO2@Carbon/SNBT) exhibits the best long-term cyclability and its capacity retention has significantly increased. The current strategy would trigger more investigations into the development of organic materials for commercialized applications.

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KW - electrochemistry

KW - hollow structures

KW - lithium ion batteries

KW - rare earth

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Organic–Rare Earth Hybrid Anode with Superior Cyclability for Lithium Ion Battery

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