Microporous Battery Electrodes from Molecular Cluster Precursors

Alexander P. Aydt; Boyu Qie; Andrew Pinkard; Long Yang; Qian Cheng; Simon J.L. Billinge; Yuan Yang; Xavier Roy

doi:10.1021/acsami.8b18149

Microporous Battery Electrodes from Molecular Cluster Precursors

Alexander P. Aydt, Boyu Qie, Andrew Pinkard, Long Yang, Qian Cheng, Simon J.L. Billinge, Yuan Yang^*, Xavier Roy

^*此作品的通讯作者

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10 引用（Scopus）

摘要

Developing novel energy storage materials is critical to many renewable energy technologies. In this work, we report on the synthesis and electrochemical properties of materials composed of porous cobalt selenide microspheres prepared from molecular cluster precursors. The cobalt selenide microspheres excel as Na ⁺ ion battery electrode materials, with a specific capacity of ∼550 mA h/g and excellent cycling stability of 85% over 100 cycles, and perform equally well as Li ⁺ ion battery electrodes with a specific capacity of ∼600 mA h/g and cycling stability of 80% over 100 cycles. Materials which reversibly store large amounts of Na ⁺ ions are uncommon, and these performances represent significant advances in the field. More broadly, this work establishes metal chalcogenide molecular clusters as valuable precursors for creating new, tunable energy storage materials.

源语言	英语
页（从-至）	11292-11297
页数	6
期刊	ACS applied materials & interfaces
卷	11
期	12
DOI	https://doi.org/10.1021/acsami.8b18149
出版状态	已出版 - 27 3月 2019
已对外发布	是

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10.1021/acsami.8b18149

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title = "Microporous Battery Electrodes from Molecular Cluster Precursors",

abstract = " Developing novel energy storage materials is critical to many renewable energy technologies. In this work, we report on the synthesis and electrochemical properties of materials composed of porous cobalt selenide microspheres prepared from molecular cluster precursors. The cobalt selenide microspheres excel as Na + ion battery electrode materials, with a specific capacity of ∼550 mA h/g and excellent cycling stability of 85% over 100 cycles, and perform equally well as Li + ion battery electrodes with a specific capacity of ∼600 mA h/g and cycling stability of 80% over 100 cycles. Materials which reversibly store large amounts of Na + ions are uncommon, and these performances represent significant advances in the field. More broadly, this work establishes metal chalcogenide molecular clusters as valuable precursors for creating new, tunable energy storage materials.",

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author = "Aydt, {Alexander P.} and Boyu Qie and Andrew Pinkard and Long Yang and Qian Cheng and Billinge, {Simon J.L.} and Yuan Yang and Xavier Roy",

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AU - Aydt, Alexander P.

AU - Qie, Boyu

AU - Pinkard, Andrew

AU - Yang, Long

AU - Cheng, Qian

AU - Billinge, Simon J.L.

AU - Yang, Yuan

AU - Roy, Xavier

PY - 2019/3/27

Y1 - 2019/3/27

N2 - Developing novel energy storage materials is critical to many renewable energy technologies. In this work, we report on the synthesis and electrochemical properties of materials composed of porous cobalt selenide microspheres prepared from molecular cluster precursors. The cobalt selenide microspheres excel as Na + ion battery electrode materials, with a specific capacity of ∼550 mA h/g and excellent cycling stability of 85% over 100 cycles, and perform equally well as Li + ion battery electrodes with a specific capacity of ∼600 mA h/g and cycling stability of 80% over 100 cycles. Materials which reversibly store large amounts of Na + ions are uncommon, and these performances represent significant advances in the field. More broadly, this work establishes metal chalcogenide molecular clusters as valuable precursors for creating new, tunable energy storage materials.

AB - Developing novel energy storage materials is critical to many renewable energy technologies. In this work, we report on the synthesis and electrochemical properties of materials composed of porous cobalt selenide microspheres prepared from molecular cluster precursors. The cobalt selenide microspheres excel as Na + ion battery electrode materials, with a specific capacity of ∼550 mA h/g and excellent cycling stability of 85% over 100 cycles, and perform equally well as Li + ion battery electrodes with a specific capacity of ∼600 mA h/g and cycling stability of 80% over 100 cycles. Materials which reversibly store large amounts of Na + ions are uncommon, and these performances represent significant advances in the field. More broadly, this work establishes metal chalcogenide molecular clusters as valuable precursors for creating new, tunable energy storage materials.

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Microporous Battery Electrodes from Molecular Cluster Precursors

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