Multiple Active Sites of Carbon for High-Rate Surface-Capacitive Sodium-Ion Storage

Guang Wang; Meng Shao; Huarui Ding; Ying Qi; Jiabiao Lian; Sheng Li; Jingxia Qiu; Huaming Li; Fengwei Huo

doi:10.1002/anie.201908159

Multiple Active Sites of Carbon for High-Rate Surface-Capacitive Sodium-Ion Storage

Guang Wang, Meng Shao, Huarui Ding, Ying Qi, Jiabiao Lian, Sheng Li, Jingxia Qiu, Huaming Li, Fengwei Huo

柔性电子（未来科技）学院|先进材料研究院

科研成果: 期刊稿件 › 文章 › 同行评审

130 引用（Scopus）

摘要

Although sodium ion batteries (SIBs) possess many beneficial features, their rate performance, cycling stability, and safety need improvement for commercial applications. Based on the mechanisms of the sodium ions storage in carbon materials, herein we present a multiple active sites decorated amorphous carbon (MAC) with rich structural defects and heteroatom doping as an anode material for SIBs. The full utilization of fast bonding–debonding processes between the active sites and sodium ions could bring a capacitive strategy to achieve superior sodium storage properties. Consequently, after materials characterization and electrochemical evaluation, the as-prepared electrode could deliver high rate and long-life performance. This active-site-related design could be extended to other types of electrode materials, thereby contributing to future practical SIB applications.

源语言	英语
页（从-至）	13584-13589
页数	6
期刊	Angewandte Chemie - International Edition
卷	58
期	38
DOI	https://doi.org/10.1002/anie.201908159
出版状态	已出版 - 16 9月 2019

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abstract = "Although sodium ion batteries (SIBs) possess many beneficial features, their rate performance, cycling stability, and safety need improvement for commercial applications. Based on the mechanisms of the sodium ions storage in carbon materials, herein we present a multiple active sites decorated amorphous carbon (MAC) with rich structural defects and heteroatom doping as an anode material for SIBs. The full utilization of fast bonding–debonding processes between the active sites and sodium ions could bring a capacitive strategy to achieve superior sodium storage properties. Consequently, after materials characterization and electrochemical evaluation, the as-prepared electrode could deliver high rate and long-life performance. This active-site-related design could be extended to other types of electrode materials, thereby contributing to future practical SIB applications.",

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AU - Wang, Guang

AU - Shao, Meng

AU - Ding, Huarui

AU - Qi, Ying

AU - Lian, Jiabiao

AU - Li, Sheng

AU - Qiu, Jingxia

AU - Li, Huaming

AU - Huo, Fengwei

PY - 2019/9/16

Y1 - 2019/9/16

N2 - Although sodium ion batteries (SIBs) possess many beneficial features, their rate performance, cycling stability, and safety need improvement for commercial applications. Based on the mechanisms of the sodium ions storage in carbon materials, herein we present a multiple active sites decorated amorphous carbon (MAC) with rich structural defects and heteroatom doping as an anode material for SIBs. The full utilization of fast bonding–debonding processes between the active sites and sodium ions could bring a capacitive strategy to achieve superior sodium storage properties. Consequently, after materials characterization and electrochemical evaluation, the as-prepared electrode could deliver high rate and long-life performance. This active-site-related design could be extended to other types of electrode materials, thereby contributing to future practical SIB applications.

AB - Although sodium ion batteries (SIBs) possess many beneficial features, their rate performance, cycling stability, and safety need improvement for commercial applications. Based on the mechanisms of the sodium ions storage in carbon materials, herein we present a multiple active sites decorated amorphous carbon (MAC) with rich structural defects and heteroatom doping as an anode material for SIBs. The full utilization of fast bonding–debonding processes between the active sites and sodium ions could bring a capacitive strategy to achieve superior sodium storage properties. Consequently, after materials characterization and electrochemical evaluation, the as-prepared electrode could deliver high rate and long-life performance. This active-site-related design could be extended to other types of electrode materials, thereby contributing to future practical SIB applications.

KW - active sites

KW - adsorption

KW - amorphous

KW - heteroatom doping

KW - sodium ion batteries

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Multiple Active Sites of Carbon for High-Rate Surface-Capacitive Sodium-Ion Storage

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