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首页> 外文期刊>Advanced energy materials >Water Invoking Interface Corrosion: An Energy Density Booster for Ni//Zn Battery
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Water Invoking Interface Corrosion: An Energy Density Booster for Ni//Zn Battery

机译:调用界面腐蚀的水:用于NI // Zn电池的能量密度助力器

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摘要

Advanced Ni//Zn batteries possess great promise that combines battery-level energy density and capacitor-level power density. However, the surface chemical reactivity of the cathode is generally restricted by active material utilization, leading to an insensitive edge site and unsatisfactory capacity. Herein, a simple and energy-saving strategy is reported for manipulating the bimetallic sulfide nanointerfaces via water invoking interface corrosion to achieve a 200% increase in the capacity of electrodes. The combined action of water and oxygen causes secondary in situ growth of NiCo-OH nanosheet coating layers on the CoxNi3-xS2 nanowalls with surface enrichment of low-valence mixed states, which deliver remarkable reactive activity and structural stability. As a result, the 3D cathode yields an ultrahigh capacity of 2.45 mAh cm(-2), higher than that of the pristine nanomaterial (1.20 mAh cm(-2)). The resulting Ni//Zn battery with excellent reversibility and long-life, achieves a remarkable energy density of 4.29 mWh cm(-2) (728 Wh kg(-1)), which is superior to most recently reported aqueous Zn-based batteries and is even comparable to Li-ion batteries. This work explores the interface corrosion mechanism and corrosion-surface activity relationship, which is a powerful strategy to construct high surface electrochemical activity of metallic sulfides/phosphides for renewable energy storage devices.
机译:Advanced Ni // Zn电池具有很大的承诺,将电池级能量密度和电容器级功率密度结合在一起。然而,阴极的表面化学反应性通常通过主动材料利用而受到限制,导致不敏感的边缘位点和不令人满意的容量。这里,据报道,通过调用界面腐蚀来操纵双金属硫化物纳米件的简单和节能策略,以实现电极容量增加200%。水和氧的组合作用在具有表面富集的低价混合状态的CoxNi-OH纳米片涂层中的嗜酸NaCO-OH纳米片涂层的二次生长,其具有显着的反应活性和结构稳定性。结果,3D阴极产生2.45mAhcm(-2)的超高容量,高于原始纳米材料(1.20mahcm(-2))。由此产生的Ni // Zn电池具有优异的可逆性和长寿命,实现了4.29 mwh cm(-2)(728WH kg(-1))的显着能量密度,其优于最近报道的基于Zn的电池水溶液甚至与锂离子电池相当。这项工作探讨了界面腐蚀机制和腐蚀表面活性关系,这是构建金属硫化物/磷化磷酸的高表面电化学活性的强大策略,用于可再生能量存储装置。

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  • 来源
    《Advanced energy materials》 |2021年第9期|2003268.1-2003268.11|共11页
  • 作者

    He Weidong; Wang Shouzhi; Shao Yongliang; Kong Zhen; Tu Huayao; Wu Yongzhong; Hao Xiaopeng;

  • 作者单位

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China|Qilu Univ Technol Dept Mat Sci & Engn Jinan 250353 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China|Qilu Univ Technol Dept Mat Sci & Engn Jinan 250353 Peoples R China;

    Shandong Univ State Key Lab Crystal Mat Jinan 250100 Peoples R China|Qilu Univ Technol Dept Mat Sci & Engn Jinan 250353 Peoples R China;

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  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类
  • 关键词

    water-interface corrosion; high chemical reactivity; high energy density; interface-reconstruction; Ni//Zn Batteries;

    机译:水界面腐蚀;高化学反应性;高能量密度;界面 - 重建;NI // Zn电池;

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