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首页> 外文期刊>Angewandte Chemie >Reducing the Charge Carrier Transport Barrier in Functionally Layer-Graded Electrodes
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Reducing the Charge Carrier Transport Barrier in Functionally Layer-Graded Electrodes

机译:在功能层分级电极中减少电荷载流子传输屏障

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摘要

Lithium-ion batteries (LIBs) are primary energy storage devices to power consumer electronics and electric vehicles, but their capacity is dramatically decreased at ultrahigh charging/discharging rates. This mainly originates from a high Li-ion/electron transport barrier within a traditional electrode, resulting in reaction polarization issues. To address this limitation, a functionally layer-graded electrode was designed and fabricated to decrease the charge carrier transport barrier within the electrode. As a proof-of-concept, functionally layer-graded electrodes composing of TiO2(B) and reduced graphene oxide (RGO) exhibit a remarkable capacity of 128 mAhg(-1) at a high charging/discharging rate of 20 C (6.7 Ag-1), which is much higher than that of a traditionally homogeneous electrode (74 mAhg(-1)) with the same composition. This is evidenced by the improvement of effective Li ion diffusivity as well as electronic conductivity in the functionally layer-graded electrodes.
机译:锂离子电池(LIBS)是发电消费电子和电动车的主要能量存储装置,但在超高充电/放电速率下它们的容量显着降低。 这主要来自传统电极内的高锂离子/电子传输屏障,导致反应极化问题。 为了解决该限制,设计了一种功能层梯度电极,以减小电极内的电荷载流子传输屏障。 作为概念证据,功能性层分级电极组成的TiO2(b)和氧化石墨烯氧化物(Rgo)的概率,高充电/放电率为20c的高充电/放电率的显着容量(6.7 Ag -1)高于具有相同组成的传统上均匀电极(74mAhg(-1))的高得多。 这通过改善有效Li离子扩散性以及功能层分级电极中的电子电导率来证明。

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  • 来源
    《Angewandte Chemie》 |2017年第47期|共6页
  • 作者

    Zhang Yanyan; Malyi Oleksandr I.; Tang Yuxin; Wei Jiaqi; Zhu Zhiqiang; Xia Huarong; Li Wenlong; Guo Jia; Zhou Xinran; Chen Zhong; Persson Clas; Chen Xiaodong;

  • 作者单位

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

    Univ Oslo Ctr Mat Sci &

    Nanotechnol Dept Phys POB 1048 NO-0316 Oslo Norway;

    Nanyang Technol Univ Sch Mat Sci &

    Engn Innovat Ctr Flexible Devices iFLEX 50 Nanyang Ave Singapore 639798 Singapore;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 应用化学;
  • 关键词

    charge carrier barrier; functionally graded electrodes; high charging rates; lithium-ion batteries; TiO2(B);

    机译:电荷载体屏障;功能梯度电极;高充电率;锂离子电池;TiO2(b);

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