Metal-organic frameworks-derived CoO/C penetrated with self-supporting graphene enabling accelerated polysulfide conversion for lithium-sulfur batteries

The lithium-sulfur (Li-S) battery is recognized as one of the most advanced batteries with superior theoretical energy density. Nevertheless, the industrial production of lithium sulfur battery is hindered by the insulation of sulfur and the shuttle behavior of soluble polysulfides. Herein, a freestanding Li-S battery cathode with a unique intercalated microstructure by penetrating graphene sheets into CoO/C polyhedrons is developed as an effective polysulfides reservoir (N-rGO@CoO/C). The unique intercalated microstructure offers continuous and rapid charge transport between the conductive matrix of N-rGO and CoO/C, effectively expediting the redox conversion of lithium polysulfides. Meanwhile, the 3D porous network provides accommodation for storing sulfur and adapts to large volume change. As a result, an impressive initial capacity of 1216 mA h g(-1) of the cell with N-rGO@CoO/C can be achieved when sulfur proportion and loading reach 72 wt% and 3.5 mg cm(-2), respectively. Moreover, the derived Li-S battery possesses an outstanding areal capacity (10.0 mA h cm(-2)) and excellent cycling stability (capacity retention of 7.47 mA h cm(-2) after 150 cycling) even with a very high sulfur loading (up to 9.6 mg cm(-2)). This study offers a feasible way for the development of self-supporting cathode and high-performance Li-S batteries. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

A unique freestanding Li-S battery cathode with intercalated microstructure has been developed, by penetrating graphene sheets into CoO/C polyhedrons, serving as an effective polysulfides reservoir. This structure enables continuous and rapid charge transport, as well as storage of sulfur and adaptation to volume change.