Abstract
? 2022Sulfurized poly(acrylonitrile) (SPAN) is an attractive cathode material for lithium-sulfur (Li-S) batteries with demonstrated stable cycling, reduced polysulfide shuttle, and low self-discharge rates. However, the sluggish reaction kinetics of SPAN cathodes greatly limit their capacity output and rate performance. Here, we report novel Se0.03SPAN/CNT-3 nanofibers as sulfur cathode materials, aiming to promote the redox kinetics of sulfur conversion by imparting both electronic conductivity and catalytic activity to SPAN. Specifically, selenium is uniformly distributed in the Se0.03SPAN/CNT-3 composite through Se–S bonds and facilitates the fast transport of Li-ions. While the CNTs embedded in nanofibers enable high electronic conductivity and provide extra contact between electrode and electrolyte, offering smooth transport channels for both electrons and ions. As a result, the Se0.03SPAN/CNT-3 cathode presents a high reversible capacity (791 mAh g?1composite at 0.2 C), superior rate performance (638 mAh g?1composite at 4 C), and extremely stable cycle life over 800 cycles. In particular, when tested in practical conditions of high areal loading (Se0.03S: 5.2 mg cm?2) and lean electrolyte (E/Se0.03S: 10 μL mg?1), this cathode delivers high reversible capacities of 733 mAh g?1composite (0.1 C) and 672 mAh g?1composite (0.2 C), demonstrating its great potential for future application.
NSTL
Elsevier