Significantly enhanced ion‐migration and sodium‐storage capability derived by strongly coupled dual interfacial engineering in heterogeneous bimetallic sulfides with densified carbon matrix

Wenxi Zhao; Xiaoqing Ma; Guangzhao Wang; Linglin Tan; Xinqin Wang; Xun He; Yan Wang; Yongsong Luo; Dongdong Zheng; Shengjun Sun; Qian Liu; Luming Li; Wei Chu; Xuping Sun

doi:10.1002/sus2.198

SusMat (Jun 2024)

Significantly enhanced ion‐migration and sodium‐storage capability derived by strongly coupled dual interfacial engineering in heterogeneous bimetallic sulfides with densified carbon matrix

Wenxi Zhao,
Xiaoqing Ma,
Guangzhao Wang,
Linglin Tan,
Xinqin Wang,
Xun He,
Yan Wang,
Yongsong Luo,
Dongdong Zheng,
Shengjun Sun,
Qian Liu,
Luming Li,
Wei Chu,
Xuping Sun

Affiliations

Wenxi Zhao: School of Electronic Information Engineering Yangtze Normal University Fuling Chongqing China
Xiaoqing Ma: School of Electronic Information Engineering Yangtze Normal University Fuling Chongqing China
Guangzhao Wang: School of Electronic Information Engineering Yangtze Normal University Fuling Chongqing China
Linglin Tan: School of Electronic Information Engineering Yangtze Normal University Fuling Chongqing China
Xinqin Wang: School of Electronic Engineering Lanzhou City University Lanzhou Gansu China
Xun He: Institute of Fundamental and Frontier Sciences University of Electronic Science and Technology of China Chengdu Sichuan China
Yan Wang: Institute of Fundamental and Frontier Sciences University of Electronic Science and Technology of China Chengdu Sichuan China
Yongsong Luo: College of Chemistry Chemical Engineering and Materials Science Shandong Normal University Jinan Shandong China
Dongdong Zheng: College of Chemistry Chemical Engineering and Materials Science Shandong Normal University Jinan Shandong China
Shengjun Sun: College of Chemistry Chemical Engineering and Materials Science Shandong Normal University Jinan Shandong China
Qian Liu: Institute for Advanced Study Chengdu University Chengdu Sichuan China
Luming Li: Institute for Advanced Study Chengdu University Chengdu Sichuan China
Wei Chu: Institute for Advanced Study Chengdu University Chengdu Sichuan China
Xuping Sun: Institute of Fundamental and Frontier Sciences University of Electronic Science and Technology of China Chengdu Sichuan China

DOI: https://doi.org/10.1002/sus2.198
Journal volume & issue: Vol. 4, no. 3
pp. n/a – n/a

Abstract

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Abstract The development of highly efficient sodium‐ion batteries depends critically on the successful exploitation of advanced anode hosts that is capable of overcoming sluggish reaction kinetics while also withstanding severe structural deformation triggered by the large radius of Na+‐insertion. Herein, a hierarchically hybrid material with hetero‐Co3S4/NiS hollow nanosphere packaged into a densified N‐doped carbon matrix (Co3S4/NiS@N‐C) was designed and fabricated utilizing CoNi‐glycerate as the self‐sacrifice template, making the utmost of the synergistic effect of hetero‐Co3S4/NiS with strong electric field and rich reaction active‐sites together with the densified outer‐carbon scaffolds with remarkable electronic conductivity and robust mechanical toughness. As anticipated, as‐fabricated Co3S4/NiS@N‐C anode affords remarkable specific capacity, prolonged cycle lifespan up to 2 400 cycles with an only 0.05% fading each cycle at 20.0 A g−1, and excellent rate feature (354.9 mAh g−1 at 30.0 A g−1), one of the best performances for most existing Co3S4/NiS‐based anodes. Ex situ structural characterizations in tandem with theoretical analysis demonstrate the reversible insertion‐conversion mechanism of initially proceeding with Na+ de‐/intercalation and superior heterogeneous interfacial reaction behavior with strong Na+‐adsorption ability. Further, sodium‐ion full cell and hybrid capacitor based on Co3S4/NiS@N‐C anode exhibit impressive electrochemical characteristics on cycling performance and rate capability, showcasing its outstanding feasibility toward practical use.

Published in SusMat

ISSN: 2766-8479 (Print); 2692-4552 (Online)
Publisher: Wiley
Country of publisher: Australia
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Materials of engineering and construction. Mechanics of materials; Technology: Engineering (General). Civil engineering (General): Environmental engineering
Website: https://onlinelibrary.wiley.com/journal/26924552

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