Enhanced gas sensing by 3D water steamed graphene hydrogel

Jin Wu; Kai Tao; Jianmin Miao; Leslie K. Norford

doi:10.1016/j.sse.2017.10.004

Enhanced gas sensing by 3D water steamed graphene hydrogel

Jin Wu, Kai Tao, Jianmin Miao, Leslie K. Norford

School of Mechanical Engineering

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

5 Scopus citations

Abstract

The interaction area and defect sites play important roles in determining the gas sensing properties of graphene. In this work, steam etching is exploited to fragment large graphene sheets on 3D graphene hydrogel (GH) to small pieces with increased defect sites. The obtained steamed graphene hydrogel (S-GH) displays three and ten times higher responses to NO₂ and NH₃, respectively, compared with its unmodified GH counterpart before steaming treatment. Furthermore, the S-GH-based NO₂ sensor exhibits a low limit of detection (LOD) of 57 ppb, which is much lower than that of a GH-based NO₂ sensor (178 ppb). This work demonstrates a facile hydrothermal steaming method to enhance the performance of graphene-based gas sensor by combining 3D structural design and defect modulation of graphene materials.

Original language	English
Pages (from-to)	101-107
Number of pages	7
Journal	Solid-State Electronics
Volume	138
DOIs	https://doi.org/10.1016/j.sse.2017.10.004
State	Published - 1 Dec 2017

Keywords

3D graphene hydrogel
Defects
Gas sensor
NH
NO
Steaming etch

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10.1016/j.sse.2017.10.004

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title = "Enhanced gas sensing by 3D water steamed graphene hydrogel",

abstract = "The interaction area and defect sites play important roles in determining the gas sensing properties of graphene. In this work, steam etching is exploited to fragment large graphene sheets on 3D graphene hydrogel (GH) to small pieces with increased defect sites. The obtained steamed graphene hydrogel (S-GH) displays three and ten times higher responses to NO2 and NH3, respectively, compared with its unmodified GH counterpart before steaming treatment. Furthermore, the S-GH-based NO2 sensor exhibits a low limit of detection (LOD) of 57 ppb, which is much lower than that of a GH-based NO2 sensor (178 ppb). This work demonstrates a facile hydrothermal steaming method to enhance the performance of graphene-based gas sensor by combining 3D structural design and defect modulation of graphene materials.",

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AU - Wu, Jin

AU - Tao, Kai

AU - Miao, Jianmin

AU - Norford, Leslie K.

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N2 - The interaction area and defect sites play important roles in determining the gas sensing properties of graphene. In this work, steam etching is exploited to fragment large graphene sheets on 3D graphene hydrogel (GH) to small pieces with increased defect sites. The obtained steamed graphene hydrogel (S-GH) displays three and ten times higher responses to NO2 and NH3, respectively, compared with its unmodified GH counterpart before steaming treatment. Furthermore, the S-GH-based NO2 sensor exhibits a low limit of detection (LOD) of 57 ppb, which is much lower than that of a GH-based NO2 sensor (178 ppb). This work demonstrates a facile hydrothermal steaming method to enhance the performance of graphene-based gas sensor by combining 3D structural design and defect modulation of graphene materials.

AB - The interaction area and defect sites play important roles in determining the gas sensing properties of graphene. In this work, steam etching is exploited to fragment large graphene sheets on 3D graphene hydrogel (GH) to small pieces with increased defect sites. The obtained steamed graphene hydrogel (S-GH) displays three and ten times higher responses to NO2 and NH3, respectively, compared with its unmodified GH counterpart before steaming treatment. Furthermore, the S-GH-based NO2 sensor exhibits a low limit of detection (LOD) of 57 ppb, which is much lower than that of a GH-based NO2 sensor (178 ppb). This work demonstrates a facile hydrothermal steaming method to enhance the performance of graphene-based gas sensor by combining 3D structural design and defect modulation of graphene materials.

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KW - Defects

KW - Gas sensor

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KW - NO

KW - Steaming etch

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Enhanced gas sensing by 3D water steamed graphene hydrogel

Abstract

Keywords

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