Heterostructured MnSe/FeSe nanorods encapsulated by carbon with enhanced Na+ diffusion as anode materials for sodium-ion batteries

[Display omitted] •Carbon-encapsulated MnSe-FeSe nanowires have been fabricated.•Heterostructure accelerates the electron transfer and ion diffusion.•MnSe-FeSe@C exhibits excellent rate capability and prolonged cycling durability. The natural abundance of sodium has fostered the development of sodiu...

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Bibliographic Details
Published in:Journal of colloid and interface science 2024-10, Vol.672, p.43-52
Main Authors: Liu, Tao, Xu, Lijun, Wang, Xuejie, Lv, Haoliang, Zhu, Bicheng, Yu, Jiaguo, Zhang, Liuyang
Format: Article
Language:English
Subjects:
Anode
Carbon encapsulation
Heterostructure
Metal selenides
Sodium-ion battery
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Summary:[Display omitted] •Carbon-encapsulated MnSe-FeSe nanowires have been fabricated.•Heterostructure accelerates the electron transfer and ion diffusion.•MnSe-FeSe@C exhibits excellent rate capability and prolonged cycling durability. The natural abundance of sodium has fostered the development of sodium-ion batteries for large-scale energy storage. However, the low capacity of the anodes hinders their future application. Herein, carbon-encapsulated MnSe-FeSe nanorods (MnSe-FeSe@C) have been fabricated by the in-situ transformation from polydopamine-coated MnO(OH)-Fe2O3. The heterostructure constructed by MnSe and FeSe nanocrystals induces the formation of built-in electric fields, accelerating electron transfer and ion diffusion, thereby improving reaction kinetics. In addition, carbon enclosure can buffer the volumetric stress and enhance the electrical conductivity. These aspects cooperatively endow the anode with superior cycling stability and distinguished rate performance. Specifically, the discharge capacity of MnSe-FeSe@C reaches 414.3 mA h g−1 at 0.1 A g−1 and 388.8 mA h g−1 even at a high current density of 5.0 A g−1. In addition, it still retains a high reversible capacity of 449.2 mA h g−1 after 700 long cycles at 1.0 A g−1. Further, the ab initio calculation has been employed to authenticate the existence of the built-in electric field by Bader charge, indicating that 0.24 electrons in MnSe were transferred to FeSe. The in-situ XRD has been used to evaluate the phase transition during the charging/discharging process, revealing the sodium ion storage mechanism. The construction of heterostructure material paves a new way to design performance-enhanced anode materials for sodium-ion batteries.
ISSN:0021-9797
1095-7103
1095-7103
DOI:10.1016/j.jcis.2024.05.220