Pea‐like MoS<sub>2</sub>@NiS<sub>1.03</sub>–carbon heterostructured hollow nanofibers for high‐performance sodium storage-Reference-Cited by-同舟云学术

Pea‐like MoS₂@NiS_1.03–carbon heterostructured hollow nanofibers for high‐performance sodium storage

Published:2023-02-27 Issue:4 Volume:5 Page:
ISSN:2637-9368
Container-title:Carbon Energy
language:en
Short-container-title:Carbon Energy

Author:

Gao Songwei¹,He Yixiang²,Yue Guichu¹,Li Huaike¹,Li Shuai¹,Liu Jingchong³,Miao Beibei¹⁴,Bai Jie⁴,Cui Zhimin¹,Wang Nü¹,Zhang Qianfan²,Jiang Lei¹⁵,Zhao Yong¹^ORCID

Affiliation:

1. Key Laboratory of Bioinspired Smart Interfacial Science and Technology of Ministry of Education, Beijing Key Laboratory of Bioinspired Energy Materials and Devices, School of Chemistry, Beijing Advanced Innovation Center for Bio‐Medical Engineering Beihang University Beijing China

2. School of Materials Science and Engineering Beihang University Beijing China

3. School of Chemistry and Biological Engineering University of Science and Technology Beijing Beijing China

4. Inner Mongolia Key Laboratory of Industrial Catalysis, Chemical Engineering College Inner Mongolia University of Technology Inner Mongolia Hohhot China

5. Laboratory of Bio‐inspired Smart Interface Science, Technical Institute of Physics and Chemistry Chinese Academy of Sciences Beijing China

Abstract

AbstractThe rational synergy of chemical composition and spatial nanostructures of electrode materials play important roles in high‐performance energy storage devices. Here, we designed pea‐like MoS2@NiS1.03–carbon hollow nanofibers using a simple electrospinning and thermal treatment method. The hierarchical hollow nanofiber is composed of a nitrogen‐doped carbon‐coated NiS1.03 tube wall, in which pea‐like uniformly discrete MoS2 nanoparticles are enclosed. As a sodium‐ion battery electrode material, the MoS2@NiS1.03–carbon hollow nanofibers have abundant diphasic heterointerfaces, a conductive network, and appropriate volume variation‐buffering spaces, which can facilitate ion diffusion kinetics, shorten the diffusion path of electrons/ion, and buffer volume expansion during Na+ insertion/extraction. It shows outstanding rate capacity and long‐cycle performance in a sodium‐ion battery. This heterogeneous hollow nanoarchitectures designing enlightens an efficacious strategy to boost the capacity and long‐life stability of sodium storage performance of electrode materials.

Publisher

Wiley

Subject

Materials Chemistry,Energy (miscellaneous),Materials Science (miscellaneous),Renewable Energy, Sustainability and the Environment

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/cey2.319

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