Interlayer ionic diffusion driven in situ QD-deposition in the Co9S8–LDH hybrid supercapacitor electrode†

IF 6 2区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Materials Chemistry Frontiers Pub Date : 2024-08-03 DOI:10.1039/D4QM00462K

Yanan Zhang, Nuo Xu, Jipeng Xu, Chi Shan, Junlei Chen, Liyuan Guo, Long Qin, Fan Wu and Wenhuan Huang

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Abstract

The micro/nano-structural design of 2D interlayers greatly enhances the electrochemical energy and kinetics of the supercapacitor electrode. Herein, a hetero-Co₉S₈ QD-doped 2D CoNi-LDH with the proper content was constructed through diverse sulfurization time, showing a 3D flower-like microsphere. The highly dispersed active QDs on 2D layers promoted both rapid ion/electron transfer kinetics and electrochemical storage capacity, which were evidenced by experiments and density functional theory calculations. As a result, the assembled hybrid supercapacitor QDs-Co₉S₈/CoNi-LDH//activated carbon displays a maximum energy density of 33.3 Wh kg⁻¹ at a power density of 820.0 W kg⁻¹. Furthermore, the in-depth analysis of interlayer ion diffusion and formation of quantum dots in heterostructure provides a good way for synthesizing high-performance electrode materials with adjustable size and composition.

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层间离子扩散驱动 Co9S8-LDH 混合超级电容器电极中的原位 QDs 沉积

二维夹层的微/纳米结构设计大大提高了作为超级电容器电极的电化学能量和动力学性能。本文通过不同的硫化时间，构建了掺杂了适当含量异质-Co9S8 QDs的二维CoNi-LDH，呈现出三维花状微球。二维层上高度分散的活性 QDs 既促进了离子/电子转移动力学的快速发展，又提高了电化学存储容量，这些都得到了实验和密度函数理论计算的证实。因此，在功率密度为 820.0 W-kg-1 时，组装的混合超级电容器 QDs-Co9S8/CoNi-LDH/ 活性炭的最大能量密度为 33.3 Wh-kg-1。此外，对异质结构中层间离子扩散和量子点形成的深入分析，为合成尺寸和成分可调的高性能电极材料提供了良好的途径。

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来源期刊

Materials Chemistry Frontiers Materials Science-Materials Chemistry

CiteScore

12.00

自引率

2.90%

发文量

313

期刊介绍： Materials Chemistry Frontiers focuses on the synthesis and chemistry of exciting new materials, and the development of improved fabrication techniques. Characterisation and fundamental studies that are of broad appeal are also welcome. This is the ideal home for studies of a significant nature that further the development of organic, inorganic, composite and nano-materials.