Ultrathin cobalt oxide nanostructures with morphology-dependent electrocatalytic oxygen evolution activity

Nan Zhang; Yin Wang; Yu Chen Hao; Yuan Man Ni; Xin Su; An Xiang Yin; Chang Wen Hu

doi:10.1039/c8nr05337e

Ultrathin cobalt oxide nanostructures with morphology-dependent electrocatalytic oxygen evolution activity

Nan Zhang, Yin Wang, Yu Chen Hao, Yuan Man Ni, Xin Su, An Xiang Yin^*, Chang Wen Hu

^*Corresponding author for this work

School of Chemistry and Chemical Engineering

Beijing Institute of Technology

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

29 Citations (Scopus)

Abstract

Engineering compositions, structures, and defects can endow nanomaterials with optimized catalytic properties. Here, we report that cobalt oxide (CoO_x) ultrathin nanosheets (UTNS, ∼1.6 nm thick) with a large number of oxygen defects and mixed cobalt valences can be obtained through a facile one-step hydrothermal protocol. The large number of oxygen defects make the ultrathin CoO_x nanosheet a superior OER catalyst with low overpotentials of 315 and 365 mV at current densities of 50 and 200 mA cm^-2, respectively. The stable framework-like architectures of the UTNS further ensure their high OER activity and durability. Our method represents a facile one-step preparation of CoO_x nanostructures with tunable compositions, morphologies, and defects, and thus promotes OER properties. This strategy may find its wider applicability in designing active, robust, and easy-to-obtain catalysts for OER and other electrocatalytic systems.

Original language	English
Pages (from-to)	20313-20320
Number of pages	8
Journal	Nanoscale
Volume	10
Issue number	43
DOIs	https://doi.org/10.1039/c8nr05337e
Publication status	Published - 21 Nov 2018

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title = "Ultrathin cobalt oxide nanostructures with morphology-dependent electrocatalytic oxygen evolution activity",

abstract = "Engineering compositions, structures, and defects can endow nanomaterials with optimized catalytic properties. Here, we report that cobalt oxide (CoOx) ultrathin nanosheets (UTNS, ∼1.6 nm thick) with a large number of oxygen defects and mixed cobalt valences can be obtained through a facile one-step hydrothermal protocol. The large number of oxygen defects make the ultrathin CoOx nanosheet a superior OER catalyst with low overpotentials of 315 and 365 mV at current densities of 50 and 200 mA cm-2, respectively. The stable framework-like architectures of the UTNS further ensure their high OER activity and durability. Our method represents a facile one-step preparation of CoOx nanostructures with tunable compositions, morphologies, and defects, and thus promotes OER properties. This strategy may find its wider applicability in designing active, robust, and easy-to-obtain catalysts for OER and other electrocatalytic systems.",

author = "Nan Zhang and Yin Wang and Hao, {Yu Chen} and Ni, {Yuan Man} and Xin Su and Yin, {An Xiang} and Hu, {Chang Wen}",

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T1 - Ultrathin cobalt oxide nanostructures with morphology-dependent electrocatalytic oxygen evolution activity

AU - Zhang, Nan

AU - Wang, Yin

AU - Hao, Yu Chen

AU - Ni, Yuan Man

AU - Su, Xin

AU - Yin, An Xiang

AU - Hu, Chang Wen

PY - 2018/11/21

Y1 - 2018/11/21

N2 - Engineering compositions, structures, and defects can endow nanomaterials with optimized catalytic properties. Here, we report that cobalt oxide (CoOx) ultrathin nanosheets (UTNS, ∼1.6 nm thick) with a large number of oxygen defects and mixed cobalt valences can be obtained through a facile one-step hydrothermal protocol. The large number of oxygen defects make the ultrathin CoOx nanosheet a superior OER catalyst with low overpotentials of 315 and 365 mV at current densities of 50 and 200 mA cm-2, respectively. The stable framework-like architectures of the UTNS further ensure their high OER activity and durability. Our method represents a facile one-step preparation of CoOx nanostructures with tunable compositions, morphologies, and defects, and thus promotes OER properties. This strategy may find its wider applicability in designing active, robust, and easy-to-obtain catalysts for OER and other electrocatalytic systems.

AB - Engineering compositions, structures, and defects can endow nanomaterials with optimized catalytic properties. Here, we report that cobalt oxide (CoOx) ultrathin nanosheets (UTNS, ∼1.6 nm thick) with a large number of oxygen defects and mixed cobalt valences can be obtained through a facile one-step hydrothermal protocol. The large number of oxygen defects make the ultrathin CoOx nanosheet a superior OER catalyst with low overpotentials of 315 and 365 mV at current densities of 50 and 200 mA cm-2, respectively. The stable framework-like architectures of the UTNS further ensure their high OER activity and durability. Our method represents a facile one-step preparation of CoOx nanostructures with tunable compositions, morphologies, and defects, and thus promotes OER properties. This strategy may find its wider applicability in designing active, robust, and easy-to-obtain catalysts for OER and other electrocatalytic systems.

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Ultrathin cobalt oxide nanostructures with morphology-dependent electrocatalytic oxygen evolution activity

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