Facile synthesis of hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure via the synergistic effect of carbonization and selenization

•Hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure is created via the synergistic effect of carbonization and selenization.•The formation and redistribution of multiple phases can create porous microstructure and expose maximum active sites.•Hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure possesses st...

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Published inElectrochimica acta Vol. 449; p. 142230
Main Authors Wang, Xiaofei, Pei, Chenchen, Zhang, Ganfan, Guo, Yue, Wang, Qian, Guo, Shouwu
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.05.2023
Subjects
Electrochemical performance
Heterostructure
Metal selenide
Sodium-ion batteries
Heterostructure
Electrochemical performance
Metal selenide
Sodium-ion batteries
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Summary:•Hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure is created via the synergistic effect of carbonization and selenization.•The formation and redistribution of multiple phases can create porous microstructure and expose maximum active sites.•Hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure possesses stable, large, fast and reversible sodium storage properties. Transition-metal selenides (TMSs) possess excellent redox reversibility and Se-rich TMSs have high theoretical specific capacity for sodium storage. Although carbon coating is a useful strategy to construct robust protective layer with additional high electronic conductivity, the formation of Se-poor TMSs inevitable results in low capacity. Herein, by simply adopting the synergistic strategy of carbonization and selenization, a novel kind of hierarchical (NiCo)Se/(NiCo)Se2@C nanostructure can be fabricated. The formation and redistribution of multiple phases can create porous structure and facilitate to expose maximum active sites, finally endowing (NiCo)Se/(NiCo)Se2@C multifunctional properties such as stable, large, fast and reversible sodium storage. The sodium-ion battery using this kind of electrode material exhibits a high initial specific capacity of 658.7 mA h g−1 at 1 A g−1, excellent rate capability of 324.9 mA h g−1 at 30 A g−1, superior cycle stability with a low capacity decay rate of 0.0046% per cycle for 1100 cycles at 20 A g−1. This work provides a facile strategy for designing unique hierarchical nanostructure for sodium-ion batteries. [Display omitted]
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2023.142230