3D heterojunction assembled via interlayer-expanded MoSe2 nanosheets anchored on N-doped branched TiO2@C nanofibers as superior anode material for sodium-ion batteries

Authors:Wang, JiuWu; Yang, Caini; Chen, Siyao; Wu, Yinping; Sun, Xian; Huang, Chenguang; Tang, Rui; Ke, Jiasheng; Dai, Yi; Situ, Yue*; Huang, Hong*
Source:Journal of Alloys and Compounds, 2023, 938: 168350.
DOI:10.1016/j.jallcom.2022.168350

Summary

High-performance sodium-ion batteries (SIBs) are highly expected in the field of large-scale static energy storage due to the low expenditure and abundant sodium resource. However, the sodium storage perfor-mance of anode materials for SIBs has suffered from the foot-dragging reaction kinetics arising from large-size Na+ during intercalation/deintercalation, which imposes more stringent requirements on the mor-phology and structure of the potential anode electrodes. Herein, we successfully designed and synthesized a three-dimensional (3D) heterojunction as anode material for SIBs, which assembled by interlayer-expanded MoSe2 nanosheets perpendicularly anchored on the nitrogen-doped branched TiO2 @C nanofibers (MoSe2 @ NBT@CNFs). Not only does the branched TiO2 @C nanofibers suppress the severe self-aggregation of MoSe2 nanosheets but also buffer the volume expansion during the cycling process. Moreover, an expanded in-terlamellar distance of MoSe2 nanosheets accelerate sodium ion diffusion, and strong chemical interactions between MoSe2 nanosheets and carbon nanofibers are conducive to improve the charge-transfer kinetics and reinforce the structural durability. As might be expected, the MoSe2 @NBT@CNFs anode can deliver excellent cycling performance with high reversibility (315.2 mAh ge1 after 800 cycles at 2 A ge1) and remarkable rate capability (194.2 mAh ge1 at 30 A ge1). The rational design strategy could offer guidance for developing high-performance metal chalcogenide-based electrode materials for SIBs.

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