Chemically functionalized 3D reticular graphene oxide frameworks decorated with MOF-derived Co^sub 3^O^sub 4^: Towards highly sensitive and selective detection to acetone

Here, we have newly developed chemically functionalized three-dimension (3D) graphene oxide hydrogels (FGH) decorated with metal-organic frameworks (MOFs)-derived Co3O4 nanostructures, in which the Co3O4 nanostructures are uniformly distributed in 3D FGH frameworks. It is found that the Co3O4/FGH co...

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Published inSensors and actuators. B, Chemical Vol. 259; p. 289
Main Authors Ding, Degong, Xue, Qingzhong, Lu, Wenbo, Xiong, Ya, Zhang, Jianqiang, Pan, Xinglong, Tao, Baoshou
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier Science Ltd 01.04.2018
Subjects
Acetone
Cobalt
Cobalt oxides
Composite materials
Electrical junctions
Electron transfer
Gas detectors
Gas sensors
Graphene
Hydrogels
Metal-organic frameworks
Molecular chains
Nanostructure
Nanostructured materials
Organic chemistry
Properties (attributes)
Response time
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Summary:Here, we have newly developed chemically functionalized three-dimension (3D) graphene oxide hydrogels (FGH) decorated with metal-organic frameworks (MOFs)-derived Co3O4 nanostructures, in which the Co3O4 nanostructures are uniformly distributed in 3D FGH frameworks. It is found that the Co3O4/FGH composites exhibits excellent acetone sensing properties, for instance, it shows an ultra-high response (Rgas/R0 = 81.2) to 50 ppm acetone, which was ∼20 times higher than that of pristine Co3O4 film, a short response time (∼20 s), and a distinct cross-selectivity against other interfering gases. Notably, upon exposure to 1 ppm acetone in air, the composites still can express an apparent response (Rgas/R0 = 4.06). The excellent acetone sensing properties of Co3O4/FGH can be mainly attributed to the unique porous structures of 3D FGH frameworks and the modulation of electrical transport properties of the Co3O4/FGH junctions in the composites. The Co3O4 nanostructures uniformly distributed in 3D FGH frameworks can easily adsorb a great amount of acetone gas molecules through the unique porous frameworks and produce a great deal of electrons, which can be transferred to the p-type FGH frameworks through Co3O4/FGH junctions so that the resistance of Co3O4/FGH composites is greatly increased. Therefore, the acetone response of the composites is dramatically enhanced because of the Co3O4/FGH junctions. This study presents a new idea of building MOF-derived oxides/FGH junctions to enhance gas response of oxide-based gas sensors, and has great potential in fabrication of new generation gas sensors.
ISSN:0925-4005
1873-3077