Issue 8, 2023

Free-standing MoSx-based dual functional polysulfide catalyzer and immobilizer for high performance Li–S batteries

Abstract

Inducing a multiple functionality/synergistic effect through rational design and utilization of functional materials is essential for high-performance prototype batteries. Herein, the controllable synthesis and simultaneous utilization of free-standing MoS3@polypyrrole nanowires@carbon paper as a functional interlayer and 1T & 2H MoS2@carbon nanowires@carbon paper as a catalytic sulfur host has been proposed. The multifunctional films of MoS3@polypyrrole nanowires@carbon paper and 1T & 2H MoS2@carbon nanowires@carbon paper can be synthesized via the same multi-step procedure based on electro- and chemical deposition. MoS3 with outstanding adsorption to polysufides, 1T & 2H hybrid MoS2 with good catalytic capability, and a 3D hierarchical crossing structure composed of polypyrrole/carbon nanowires on carbon paper build a strong barrier to lithium polysulfides and effectively promote the redox reaction. The prepared Li–S battery with simultaneous use of MoS3@polypyrrole nanowires@carbon paper as the interlayer and 1T & 2H MoS2@carbon nanowires@carbon paper as the sulfur host can achieve a high initial discharge capacity of 1447 mA h g−1 at 0.2 C and stable long-term cycling at 1 C with a capacity decay rate of 0.035% per cycle after 500 cycles. The synergistic engineering proposed in this work provides new insight and opportunities for the development of advanced Li–S batteries towards their practical applications.

Graphical abstract: Free-standing MoSx-based dual functional polysulfide catalyzer and immobilizer for high performance Li–S batteries

Supplementary files

Article information

Article type
Research Article
Submitted
21 Dec 2022
Accepted
18 Feb 2023
First published
20 Feb 2023

Mater. Chem. Front., 2023,7, 1659-1670

Free-standing MoSx-based dual functional polysulfide catalyzer and immobilizer for high performance Li–S batteries

B. Shi, Y. Wang, C. Zhang, X. Chen, E. Liu, S. Mei and C. Yao, Mater. Chem. Front., 2023, 7, 1659 DOI: 10.1039/D2QM01328B

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