• 主题
高级搜索  >
历史搜索 清空历史
首页> 外文期刊>Advanced Functional Materials >2D Nanospace Confined Synthesis of Pseudocapacitance- Dominated MoS_2-in-Ti_3C_2 Superstructure for Ultrafast and Stable Li/Na-lon Batteries
【24h】

2D Nanospace Confined Synthesis of Pseudocapacitance- Dominated MoS_2-in-Ti_3C_2 Superstructure for Ultrafast and Stable Li/Na-lon Batteries

机译:超快且稳定的锂/钠离子电池的伪电容主导的MoS_2-in-Ti_3C_2超结构的二维纳米空间受限合成

获取原文
获取原文并翻译 | 示例
           
页面导航
  • 摘要
  • 著录项
  • 相似文献
  • 相关主题

摘要

Exploring a universal strategy to implement the precise control of 2D nanomaterials in size and layer number is a big challenge for achieving ultrafast and stable Li/Na-ion batteries. Herein, the confined synthesis of 1-3 layered MoS2 nanocrystals into 2D Ti3C2 interlayer nanospace with the help of electrostatic attraction and subsequent cetyltrimethyl ammonium bromide (CTAB) directed growth is reported. The MoS2 nanocrystals are tightly anchored into the interlayer by 2D confinement effect and strong MoC covalent bond. Impressively, the disappearance of Li+ intercalated into MoS2 reduction peak is successfully observed for the first time in the experiment, showing in a typical surface-controlled charge storage behavior. The pseudocapacitance-dominated contribution guarantees a much faster and more stable Li/Na storage performance. As predicted, this electrode exhibits a very high Li+ storage capacity of 340 mAh g(-1) even at 20 A g(-1) and a long cycle life (1000 times). It also shows an excellent Na+ storage capacity of 310 mAh g(-1) at 1 A g(-1) with a 1600 times high-rate cycling. Such impressive confined synthesis strategy can be extended to the precise control of other 2D nanomaterials.
机译:探索实现二维纳米材料的尺寸和层数精确控制的通用策略,对于实现超快速和稳定的锂/钠离子电池来说是一个巨大的挑战。本文中,报道了借助于静电吸引和随后的十六烷基三甲基溴化铵(CTAB)定向生长的将1-3个层状的MoS 2纳米晶体限制合成到2D Ti 3 C 2层间纳米空间中的方法。 MoS2纳米晶体通过2D约束效应和强大的MoC共价键牢固地锚定在中间层中。令人印象深刻的是,在实验中首次成功观察到嵌入MoS2还原峰中的Li +的消失,表现出典型的表面控制电荷存储行为。伪电容为主的贡献可确保更快,更稳定的Li / Na存储性能。如预测的那样,即使在20 A g(-1)时,该电极也具有340 mAh g(-1)的极高Li +储存容量和长循环寿命(> 1000倍)。它还显示出在1 A g(-1)下具有310 mAh g(-1)的出色Na +存储容量,并具有1600倍的高循环率。这种令人印象深刻的受限合成策略可以扩展到其他2D纳米材料的精确控制。

著录项

  • 来源
    《Advanced Functional Materials》 |2018年第40期|1804306.1-1804306.9|共9页
  • 作者

    Ma Kun; Jiang Hao; Hu Yanjie; Li Chunzhong;

  • 作者单位

    East China Univ Sci & Technol, Sch Mat Sci & Engn, Minist Educ, Key Lab Ultrafine Mat, Shanghai 200237, Peoples R China;

    East China Univ Sci & Technol, Sch Mat Sci & Engn, Minist Educ, Key Lab Ultrafine Mat, Shanghai 200237, Peoples R China;

    East China Univ Sci & Technol, Sch Mat Sci & Engn, Minist Educ, Key Lab Ultrafine Mat, Shanghai 200237, Peoples R China;

    East China Univ Sci & Technol, Sch Mat Sci & Engn, Minist Educ, Key Lab Ultrafine Mat, Shanghai 200237, Peoples R China;

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

    confined synthesis; energy storage; high rate; MoS2 nanocrystals; pseudocapacitance;

    机译:受限合成;储能;高速率;MoS2纳米晶体;伪电容;

相似文献

  • 外文文献
  • 中文文献
  • 专利
获取原文

客服邮箱:kefu@zhangqiaokeyan.com

京公网安备:11010802029741号 ICP备案号:京ICP备15016152号-6 六维联合信息科技 (北京) 有限公司©版权所有

  • 客服微信

  • 服务号