Enhancing sodium storage through tri-phase heterointerfaces in Co–Fe–MoSe2@N-doped carbon nanocubes with self-generated rich phase boundaries

Transition metal selenides have received considerable research interest as conversion-type anodes owing to their impressive theoretical specific capacity and high conversion reaction efficiency. Nevertheless, the practical application of these materials is constrained by the low intrinsic conductivi...

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Bibliographic Details
Published in:Journal of alloys and compounds 2024-06, Vol.987, p.174177, Article 174177
Main Authors: Wang, Chao, Wan, Jiandong, Li, Junzhe, Zhang, Longhai, Wang, Rui, Liu, Yangyang, Ma, Yangzhou, Qin, Qingqing, Qian, Meiyi, Li, Hongbao, Zhang, Chaofeng
Format: Article
Language:English
Subjects:
Conversion reaction
Co–Fe–MoSe2
Heterostructure
Sodium ion storage
Tri-phase interface
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Summary:Transition metal selenides have received considerable research interest as conversion-type anodes owing to their impressive theoretical specific capacity and high conversion reaction efficiency. Nevertheless, the practical application of these materials is constrained by the low intrinsic conductivity and substantial volume changes during repetitive cycles, which leads to electrode structure deterioration, reduced cyclic stability, and poor rate performance. Herein, a trimetallic selenide Co–Fe–MoSe2@N-doped carbon composite with self-generated abundant phase boundaries was successfully designed using a straightforward co-precipitation method followed by a selenization process. The hybrid material, with its inherent self-generated electric field at the heterojunction surfaces, significantly improves the reaction kinetics. Moreover, the experimental results, complemented with density functional theory calculations, also illustrate that the enriched heterostructure boundaries provide ample electrochemical reaction active sites, thereby boosting charge transfer efficiency and mitigating the Na+ diffusion barrier. Remarkably, the composite exhibits excellent cyclic performance, achieving 322.4 mAh g−1 at 5 A g−1 after 1000 cycles, surpassing the performance of various other metal selenides. This innovative approach of creating abundant phase boundaries through the heterostructured ternary metal selenide presents a promising avenue for advancing the practical application of conversion-type anode materials. •Co–Fe–MoSe2@NC heterostructures with abundant phase boundaries are fabricated.•The N-doped carbon skeletons increase the conductivity and retain structural stability.•The self-built electric field derived from the heterostructure improves the reaction kinetics.•Ex-situ XRD analysis and DFT calculation provide insight into the Na+ storage and reinforcement mechanism.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2024.174177