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Design of Janus Heterostructures Embedded in Carbon Nanofibers via Heterointerface and Structural Engineering for Rapid Polysulfide Conversion

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Zhang, Xiaofei
Wang, Tongzhen
Li, Yulei
Yang, Jie
Cui, Jiewu
Yan, Jian
Liu, Jiaqin
Tan, Hark Hoe
Yu, Yan
Wu, Yucheng

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The sluggish redox kinetics of sulfur electrode and the “shuttle effect” caused by soluble lithium polysulfides (LiPS) are critical challenges in the advancement of high-energy lithium-sulfur batteries. Here, a pioneering flexible self-supporting composite scaffold that incorporates Janus V2O3/VN heterostructures embedded within multichannel nitrogen-doped carbon nanofibers (MNCNF) is introduced. The MNCNF features a 3D hierarchical porous conductive network that facilitates rapid ion/electron transport while offering substantial space for high sulfur loading. Theoretical calculations demonstrate that the Janus V2O3/VN heterocatalyst, featuring a built-in interfacial electric field, facilitates a smooth and rapid “capture-diffusion-conversion” of LiPS by leveraging the V2O3’s strong adsorption capacity, VN's high catalytic capability and promoted interfacial charge/ion transport, thereby accelerating bi-directional sulfur conversion. The as-designed sulfur electrode with a sulfur loading of 2.0 mg cm−2 showcases high rate capability of 618 mAh g⁻¹ at 5C with 68.1% capacity retention over 500 cycles. Notably, under harsh conditions of high sulfur loading (6.0 mg cm−2) and lean electrolyte (7.5 µL mg−1), it achieves a high initial areal capacity of 4.92 mAh cm−2 with 94.8% capacity retention over 150 cycles. This work offers valuable insights for the rational design of optimal vanadium-based heterocatalysts aimed at facilitating rapid sulfur redox conversion.

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