Isolated Single-Atom Ni-N5 Catalytic Site in Hollow Porous Carbon Capsules for Efficient Lithium-Sulfur Batteries

Lithium-sulfur (Li-S) batteries suffer from multiple complex and often interwoven issues, such as the low electronic conductivity of sulfur and Li2S/Li2S2, shuttle effect, and sluggish electrochemical kinetics of lithium polysulfides (LiPSs). Guided by theoretical calculations, a multifunctional catalyst of isolated single-atom nickel in an optimal Ni-N-5 active moiety incorporated in hollow nitrogen-doped porous carbon (Ni-N-5/HNPC) is constructed and acts as an ideal host for a sulfur cathode. The host improved electrical conductivity, enhanced physical-chemical dual restricting capability toward LiPSs, and, more importantly, boosted the redox reaction kinetics by the Ni-N-5 active moiety. Therefore, the Ni-N-5/HNPC/S cathode exhibits superior rate performance, long-term cycling stability, and good areal capacity at high sulfur loading. This work highlights the important role of the coordination number of active centers in single-atom catalysts and provides a strategy to design a hollow nanoarchitecture with single-atom active sites for high-performance Li-S batteries.

Automated summary

By constructing a multifunctional catalyst of isolated single-atom nickel in hollow nitrogen-doped porous carbon (Ni-N-5/HNPC), the performance of lithium-sulfur batteries has been successfully enhanced, including improved electrical conductivity, enhanced physical-chemical restriction capability towards lithium polysulfides, and boosted redox reaction kinetics.