硒限制在ZIF-8衍生多孔carbon@MWCNTs三维网络:定制反应动力学高性能锂硒电池

Chemical Synthesis Pub Date : 1900-01-01 DOI:10.20517/cs.2022.04

Hongyan Li, C. Li, Yingying Wang, Ming‐Hui Sun, Wenda Dong, Yu Li, Bao‐Lian Su

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引用次数: 4

摘要

锂硒电池目前是一种与商用锂离子电池高度竞争的技术，因为它具有3253毫安时cm-3的高容量和675毫安时g-1的重量容量。然而，锂硒(Li-Se)电池的实际应用受到可溶多硒化物在循环过程中的穿梭效应的阻碍。本文报道了金属-有机骨架分子筛咪唑盐骨架-8 (ZIF-8)在三维(3D)互联高导电多壁碳纳米管(MWCNTs)上的原位生长和热解。所获得的复合材料用于固定先进的锂硒电池中的硒。与分离的ZIF-8衍生的微孔碳相比，我们合成的ZIF-8衍生的多孔carbon@MWCNTs (ZIF-8-C@MWCNTs) 3D高导电性网络促进了锂离子的扩散和电子传递。ZIF-8晶体的粒径大小对电池性能有重要影响。通过调整ZIF-8的粒径，可以调节ZIF-8-C@MWCNTs三维网络中的电化学反应动力学。在MWCNTs复合材料表面包覆的ZIF-8的优化粒径约为300-500 nm，在0.2℃下循环200次后，ZIF-8的初始放电容量为756 mAh g-1，稳定容量为468 mAh g-1。将3D MWCNTs与适当尺寸的ZIF-8衍生微孔碳颗粒相结合，可以大大提高锂硒电池的性能。这项工作为高性能锂硒电池的进一步结构设计和基质粒径选择提供了重要的指导。

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Selenium confined in ZIF-8 derived porous carbon@MWCNTs 3D networks: tailoring reaction kinetics for high performance lithium-selenium batteries

Lithium-selenium battery is nowadays a highly competing technology to the commercial Li-ion battery because it has a high volumetric capacity of 3253 mAh cm-3 and gravimetric capacity of 675 mAh g-1. However, the practical application of lithium-selenium (Li-Se) batteries is impeded by the shuttle effect of the soluble polyselenides during the cycling process. Herein, we report the in situ growth and pyrolysis of the metal-organic framework zeolitic imidazolate framework-8 (ZIF-8) on three-dimensional (3D) interconnected highly conductive multiwalled carbon nanotubes (MWCNTs). The obtained composites are used to anchor Se for advanced Li-Se batteries. Compared with the isolated ZIF-8 derived microporous carbon, our synthesized ZIF-8 derived porous carbon@MWCNTs (ZIF-8-C@MWCNTs) 3D highly conductive networks facilitate lithium ion diffusion and electron transportation. The particle size of ZIF-8 crystals has an important impact on the battery performance. By adjusting the particle size of ZIF-8, the electrochemical reaction kinetics in ZIF-8-C@MWCNTs 3D networks can be tuned. The optimized particle size of ZIF-8 around 300-500 nm coated on MWCNTs composite achieves an excellent initial discharge capacity of 756 mAh g-1 and a stabilized capacity of 468 mAh g-1 at 0.2 C after 200 cycles. Combining the 3D MWCNTs with the appropriate size of ZIF-8 derived microporous carbon particles could highly improve the performance of the Li-Se battery. This work provides significant guidance for further structural design and host particle size selection for high-performance Li-Se batteries.

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来源期刊

Chemical Synthesis

CiteScore

3.40

自引率

0.00%

发文量