CoSe2 nanodots confined in multidimensional porous nanoarchitecture towards efficient sodium ion storage

Sodium ion batteries (SIBs) are a low-cost and promising alternative to lithium ion batteries, however, due to the large sodium ion size (Na+ vs Li+: 1.02 Å vs 0.76 Å), high ion diffusion barrier and huge volume variation of electrode materials, it remains a challenge to achieve satisfactory Na+ sto...

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Bibliographic Details
Published in:Nano energy 2022-07, Vol.98, p.107326, Article 107326
Main Authors: Xiao, Qian, Song, Qilin, Zheng, Ke, Zheng, Li, Zhu, Yanyan, Chen, Zhonghui
Format: Article
Language:English
Subjects:
Multidimensional nanoarchitecture
Porous carbon nanowires
Sodium ion batteries
Three-dimensional graphene
Ultrasmall nanodots
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Summary:Sodium ion batteries (SIBs) are a low-cost and promising alternative to lithium ion batteries, however, due to the large sodium ion size (Na+ vs Li+: 1.02 Å vs 0.76 Å), high ion diffusion barrier and huge volume variation of electrode materials, it remains a challenge to achieve satisfactory Na+ storage performance. To address these issues, herein, we deliberately designed a multidimensional porous anode for SIBs, which was constructed by zero-dimensional (0D) ultrasmall CoSe2 nanodots confined in one-dimensional (1D) porous carbon nanowires (CNWs) and well encapsulated within three-dimensional (3D) graphene (3DG/CoSe2@CNWs). The fabricated 3DG/CoSe2@CNWs nanoarchitecture exhibits plentiful reactive sites, interconnected conductive network, abundant ion transport channels, and double protective structure. Thus, it showed enhanced Na+ storage performance with high reversible capacities (543 mA h g−1 at 0.1 A g−1) and superior long-term cycling performance with a capacity retention of 86.1% at 2 A g−1, and when coupled with 3D graphene/Prussian blue (3DG/PB) cathodes, the full batteries also delivered enhanced electrochemical performance. Furthermore, its efficient Na+ storage mechanisms were proved by the reaction kinetics analysis and density functional theory calculations. Our work provides a new electrode design strategy based on multidimensional nanoarchitecture for high-performance energy storage devices. [Display omitted] •A multidimensional 3DG/CoSe2@CNWs nanoarchitecture was designed and prepared via a one-step selenization strategy.•The 3DG/CoSe2@CNWs anode exhibited a high reversible capacity of 543 mA h g−1 and superior cycle life over 500 times.•The full batteries with the 3DG/PB as cathode delivered enhanced electrochemical performance.•The efficient Na+ storage mechanisms were proved by the reaction kinetics analysis and density functional theory calculations.
ISSN:2211-2855
DOI:10.1016/j.nanoen.2022.107326