Three-dimensional graphene framework with ultra-high sulfur content for a robust lithium-sulfur battery

• Published in: Nano research Vol. 9; no. 1; pp. 240 - 248
• Main Authors: Papandrea, Benjamin, Xu, Xu, Xu, Yuxi, Chen, Chih-Yen, Lin, Zhaoyang, Wang, Gongming, Luo, Yanzhu, Liu, Matthew, Huang, Yu, Mai, Liqiang, Duan, Xiangfeng
• Format: Journal Article
• Language: English
• Published: Beijing Tsinghua University Press 2016; Springer Nature B.V
• Subjects: Additives; Atomic/Molecular Structure and Spectra; Binders; Biomedicine; Biotechnology; Cathodes; Chemistry and Materials Science; Condensed Matter Physics; Conductivity; Electric vehicles; Electrochemistry; Electronic devices; Energy storage; Fuel consumption; Graphene; Ion transport; Lithium; Lithium sulfur batteries; Lithium-ion batteries; Materials Science; Nanostructure; Nanotechnology; Polysulfides; Research Article; Robustness; Specific capacity; Storage batteries; Sulfur; Three dimensional; 三维; 复合材料; 多孔结构; 框架; 石墨; 硫含量; 能量储存; 锂离子电池; three-dimensional (3D)-network; energy storage; graphene framework; lithium sulfur battery; high loading
• ISSN: 1998-0124; 1998-0000
• DOI: 10.1007/s12274-016-1005-1

Lithium-sulfur batteries can deliver significantly higher specific capacity than standard lithium ion batteries, and represent the next generation of energy storage devices for both electric vehicles and mobile devices. However, the lithium-sulfur technology today is plagued with numerous challenges, including poor sulfur conductivity, large volumetric expansion, severe polysulfide shuttling and low sulfur utilization, which prevent its wide-spread adoption in the energy storage industry. Here we report a freestanding three-dimensional （3D） graphene frame- work for highly efficient loading of sulfur particles and creating a high capacity sulfur cathode. Using a one-pot synthesis method, we show a mechanically robust graphene-sulfur composite can be prepared with the highest sulfur weight content （90% sulfur） reported to date, and can be directly used as the sulfur cathode without additional binders or conductive additives. The graphene-sulfur composite features a highly interconnected graphene network ensuring excellent conductivity and a 3D porous structure allowing efficient ion transport and accommodating large volume expansion. Additionally, the 3D graphene framework can also function as an effective encapsulation layer to retard the polysulfide shuttling effect, thus enabling a highly robust sulfur cathode. Electrochemical studies show that such composite can deliver a highest capacity of 969 mAh-g-1, a record high number achieved for all sulfur cathodes reported to date when normalized by the total mass of the entire electrode. Our studies demonstrate that the 3D graphene framework represents an attractive scaffold material for a high performance lithium sulfur battery cathode, and could enable exciting opportunities for ultra-high capacity energy storage applications.