Stereoassembled V2O5@FeOOH Hollow Architectures with Lithiation Volumetric Strain Self-Reconstruction for Lithium-Ion Storage

Yao Zhang; Kun Rui; Aoming Huang; Ying Ding; Kang Hu; Wenhui Shi; Xiehong Cao; Huijuan Lin; Jixin Zhu; Wei Huang

doi:10.34133/2020/2360796

Stereoassembled V2O5@FeOOH Hollow Architectures with Lithiation Volumetric Strain Self-Reconstruction for Lithium-Ion Storage

Yao Zhang, Kun Rui, Aoming Huang, Ying Ding, Kang Hu, Wenhui Shi, Xiehong Cao, Huijuan Lin, Jixin Zhu, Wei Huang

Institute of Flexible Electronics

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

Vanadium oxides have recently attracted widespread attention due to their unique advantages and have demonstrated promising chemical and physical properties for energy storage. This work develops a mild and efficient method to stereoassemble hollow V2O5@FeOOH heterostructured nanoflowers with thin nanosheets. These dual-phased architectures possess multiple lithiation voltage plateau and well-defined heterointerfaces facilitating efficient charge transfer, mass diffusion, and self-reconstruction with volumetric strain. As a proof of concept, the resulting V2O5@FeOOH hollow nanoflowers as an anode material for lithiumion batteries (LIBs) realize high-specific capacities, long lifespans, and superior rate capabilities, e.g., maintaining a specific capacity as high as 985 mAhga'1 at 200mAga'1 with good cyclability.

Original language	English
Article number	2360796
Journal	Research
Volume	2020
DOIs	https://doi.org/10.34133/2020/2360796
State	Published - 8 Apr 2020

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title = "Stereoassembled V2O5@FeOOH Hollow Architectures with Lithiation Volumetric Strain Self-Reconstruction for Lithium-Ion Storage",

abstract = "Vanadium oxides have recently attracted widespread attention due to their unique advantages and have demonstrated promising chemical and physical properties for energy storage. This work develops a mild and efficient method to stereoassemble hollow V2O5@FeOOH heterostructured nanoflowers with thin nanosheets. These dual-phased architectures possess multiple lithiation voltage plateau and well-defined heterointerfaces facilitating efficient charge transfer, mass diffusion, and self-reconstruction with volumetric strain. As a proof of concept, the resulting V2O5@FeOOH hollow nanoflowers as an anode material for lithiumion batteries (LIBs) realize high-specific capacities, long lifespans, and superior rate capabilities, e.g., maintaining a specific capacity as high as 985 mAhga'1 at 200mAga'1 with good cyclability.",

author = "Yao Zhang and Kun Rui and Aoming Huang and Ying Ding and Kang Hu and Wenhui Shi and Xiehong Cao and Huijuan Lin and Jixin Zhu and Wei Huang",

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doi = "10.34133/2020/2360796",

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T1 - Stereoassembled V2O5@FeOOH Hollow Architectures with Lithiation Volumetric Strain Self-Reconstruction for Lithium-Ion Storage

AU - Zhang, Yao

AU - Rui, Kun

AU - Huang, Aoming

AU - Ding, Ying

AU - Hu, Kang

AU - Shi, Wenhui

AU - Cao, Xiehong

AU - Lin, Huijuan

AU - Zhu, Jixin

AU - Huang, Wei

PY - 2020/4/8

Y1 - 2020/4/8

N2 - Vanadium oxides have recently attracted widespread attention due to their unique advantages and have demonstrated promising chemical and physical properties for energy storage. This work develops a mild and efficient method to stereoassemble hollow V2O5@FeOOH heterostructured nanoflowers with thin nanosheets. These dual-phased architectures possess multiple lithiation voltage plateau and well-defined heterointerfaces facilitating efficient charge transfer, mass diffusion, and self-reconstruction with volumetric strain. As a proof of concept, the resulting V2O5@FeOOH hollow nanoflowers as an anode material for lithiumion batteries (LIBs) realize high-specific capacities, long lifespans, and superior rate capabilities, e.g., maintaining a specific capacity as high as 985 mAhga'1 at 200mAga'1 with good cyclability.

AB - Vanadium oxides have recently attracted widespread attention due to their unique advantages and have demonstrated promising chemical and physical properties for energy storage. This work develops a mild and efficient method to stereoassemble hollow V2O5@FeOOH heterostructured nanoflowers with thin nanosheets. These dual-phased architectures possess multiple lithiation voltage plateau and well-defined heterointerfaces facilitating efficient charge transfer, mass diffusion, and self-reconstruction with volumetric strain. As a proof of concept, the resulting V2O5@FeOOH hollow nanoflowers as an anode material for lithiumion batteries (LIBs) realize high-specific capacities, long lifespans, and superior rate capabilities, e.g., maintaining a specific capacity as high as 985 mAhga'1 at 200mAga'1 with good cyclability.

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Stereoassembled V2O5@FeOOH Hollow Architectures with Lithiation Volumetric Strain Self-Reconstruction for Lithium-Ion Storage

Abstract

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