Size effect induced activity enhancement and anti-photocorrosion of reduced graphene oxide/ZnO composites for degradation of organic dyes and reduction of Cr(VI) in water
RGO/ZnO composites with different size of ZnO particles have been fabricated via a one-step facile solvothermal method. The photocatalytic activities of these composites have been investigated toward dye degradation and Cr (IV) reduction in an aqueous phase. It is found that ZnO-S1, with relatively...
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| Published in | Applied catalysis. B, Environmental Vol. 140-141; pp. 598 - 607 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
Kidlington
Elsevier B.V
01.08.2013
Elsevier |
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| Abstract | RGO/ZnO composites with different size of ZnO particles have been fabricated via a one-step facile solvothermal method. The photocatalytic activities of these composites have been investigated toward dye degradation and Cr (IV) reduction in an aqueous phase. It is found that ZnO-S1, with relatively small particles size distribution, is able to hybridize with RGO sheet more efficiently than that for the hybridization of ZnO-S2, with large particles size distribution, with RGO sheet. Such a particle size effect leads the more efficient interfacial interaction between ZnO-S1 and RGO, which leads to both the enhanced photoactivity and the significantly decreased photocorrosion. In addition, we have also used the radicals scavengers technique to study the role of photoactive species involved in the photocatalytic degradation of dye and reduction of Cr (VI).
•Particles size of ZnO strongly influences the photocatalytic performance of RGO/ZnO composites.•The photocorrosion of ZnO is inhibited by the hybridization of RGO with ZnO in an appropriate manner.•Possible photocatalytic reaction mechanism over RGO/ZnO composites has been studied.
The composites of reduced graphene oxide/ZnO (RGO/ZnO) with different particles size of ZnO have been prepared via a facile solvothermal reaction of graphene oxide (GO) and ZnO in an ethanol-water solvent. It is found that the RGO/ZnO-S1 composite with ZnO particle size of 20–100nm exhibits the enhanced photoactivity toward degradation of organic dyes and reduction of heavy metal ions Cr(VI) in water as compared to the bare ZnO-S1 sample under UV light irradiation. However, the RGO/ZnO-S2 composite with ZnO particle size of 50–500nm shows decreased photoactivity as compared to bare ZnO-S2. The recycled photoactivity testing shows that, for RGO/ZnO-S1, the photocorrosion of ZnO-S1 is efficiently inhibited by the hybridization with RGO whereas the case is not for RGO/ZnO-S2. A collection of characterization techniques disclose that the smaller particles size for RGO/ZnO-S1 than that for RGO/ZnO-S2 leads to a more interfacial contact and a chemical bonding between RGO and ZnO-S1, thereby resulting in enhanced photoactivity and efficient anti-photocorrosion as observed for RGO/ZnO-S1. Furthermore, the possible reaction mechanism for degradation of dyes and reduction of Cr(VI) over RGO/ZnO-S1 has also been studied. Our results suggest that the semiconductor particles size has an important effect on the photocatalytic performance of RGO/semiconductor composites photocatalysts. The hybridization of RGO with ZnO in an appropriate manner is able to significantly inhibit the well-known photocorrosion of semiconductor ZnO. It is anticipated that this work would enrich the applications of RGO/semiconductor photocatalysts in environment purification. |
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| AbstractList | RGO/ZnO composites with different size of ZnO particles have been fabricated via a one-step facile solvothermal method. The photocatalytic activities of these composites have been investigated toward dye degradation and Cr (IV) reduction in an aqueous phase. It is found that ZnO-S1, with relatively small particles size distribution, is able to hybridize with RGO sheet more efficiently than that for the hybridization of ZnO-S2, with large particles size distribution, with RGO sheet. Such a particle size effect leads the more efficient interfacial interaction between ZnO-S1 and RGO, which leads to both the enhanced photoactivity and the significantly decreased photocorrosion. In addition, we have also used the radicals scavengers technique to study the role of photoactive species involved in the photocatalytic degradation of dye and reduction of Cr (VI).
•Particles size of ZnO strongly influences the photocatalytic performance of RGO/ZnO composites.•The photocorrosion of ZnO is inhibited by the hybridization of RGO with ZnO in an appropriate manner.•Possible photocatalytic reaction mechanism over RGO/ZnO composites has been studied.
The composites of reduced graphene oxide/ZnO (RGO/ZnO) with different particles size of ZnO have been prepared via a facile solvothermal reaction of graphene oxide (GO) and ZnO in an ethanol-water solvent. It is found that the RGO/ZnO-S1 composite with ZnO particle size of 20–100nm exhibits the enhanced photoactivity toward degradation of organic dyes and reduction of heavy metal ions Cr(VI) in water as compared to the bare ZnO-S1 sample under UV light irradiation. However, the RGO/ZnO-S2 composite with ZnO particle size of 50–500nm shows decreased photoactivity as compared to bare ZnO-S2. The recycled photoactivity testing shows that, for RGO/ZnO-S1, the photocorrosion of ZnO-S1 is efficiently inhibited by the hybridization with RGO whereas the case is not for RGO/ZnO-S2. A collection of characterization techniques disclose that the smaller particles size for RGO/ZnO-S1 than that for RGO/ZnO-S2 leads to a more interfacial contact and a chemical bonding between RGO and ZnO-S1, thereby resulting in enhanced photoactivity and efficient anti-photocorrosion as observed for RGO/ZnO-S1. Furthermore, the possible reaction mechanism for degradation of dyes and reduction of Cr(VI) over RGO/ZnO-S1 has also been studied. Our results suggest that the semiconductor particles size has an important effect on the photocatalytic performance of RGO/semiconductor composites photocatalysts. The hybridization of RGO with ZnO in an appropriate manner is able to significantly inhibit the well-known photocorrosion of semiconductor ZnO. It is anticipated that this work would enrich the applications of RGO/semiconductor photocatalysts in environment purification. The composites of reduced graphene oxide/ZnO (RCO/ZnO) with different particles size of ZnO have been prepared via a facile solvothermal reaction of graphene oxide (GO) and ZnO in an ethanol-water solvent. It is found that the RGO/ZnO-Sl composite with ZnO particle size of 20-100 nm exhibits the enhanced photoactivity toward degradation of organic dyes and reduction of heavy metal ions Cr(VI) in water as compared to the bare ZnO-Sl sample under UV light irradiation. However, the RGO/ZnO-S2 composite with ZnO particle size of 50-500 nm shows decreased photoactivity as compared to bare ZnO-S2. The recycled photoactivity testing shows that, for RGO/ZnO-Sl. the photocorrosion of ZnO-Sl is efficiently inhibited by the hybridization with RGO whereas the case is not for RGO/ZnO-S2. A collection of characterization techniques disclose that the smaller particles size for RGO/ZnO-S1 than that for RGO/ZnO-S2 leads to a more interfacial contact and a chemical bonding between RGO and ZnO-S1. thereby resulting in enhanced photoactivity and efficient anti-photocorrosion as observed for RGO/ZnO-S1. Furthermore, the possible reaction mechanism for degradation of dyes and reduction of Cr(VI) over RGO/ZnO-S1 has also been studied. Our results suggest that the semiconductor particles size has an important effect on the photocatalytic performance of RGO/semiconductor composites photocatalysts. The hybridization of RGO with ZnO in an appropriate manner is able to significantly inhibit the well-known photocorrosion of semiconductor ZnO. It is anticipated that this work would enrich the applications of RGO/semiconductor photocatalysts in environment purification. |
| Author | Zhang, Yanhui Xu, Yi-Jun Chen, Zhang Liu, Siqi |
| Author_xml | – sequence: 1 givenname: Yanhui surname: Zhang fullname: Zhang, Yanhui organization: State Key Laboratory Breeding Base of Photocatalysis, College of Chemistry and Chemical Engineering, Fuzhou University, Fuzhou 350002, PR China – sequence: 2 givenname: Zhang surname: Chen fullname: Chen, Zhang organization: State Key Laboratory Breeding Base of Photocatalysis, College of Chemistry and Chemical Engineering, Fuzhou University, Fuzhou 350002, PR China – sequence: 3 givenname: Siqi surname: Liu fullname: Liu, Siqi organization: State Key Laboratory Breeding Base of Photocatalysis, College of Chemistry and Chemical Engineering, Fuzhou University, Fuzhou 350002, PR China – sequence: 4 givenname: Yi-Jun surname: Xu fullname: Xu, Yi-Jun email: yjxu@fzu.edu.cn organization: State Key Laboratory Breeding Base of Photocatalysis, College of Chemistry and Chemical Engineering, Fuzhou University, Fuzhou 350002, PR China |
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| Keywords | Size and synergetic effect ZnO Interfacial contact Reduced graphene oxide Photostability Water Binary compound Organic dye Composite material Degradation Chemical reduction Heterogeneous catalysis Size effect Graphene oxide Interface Environmental protection |
| Language | English |
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| Snippet | RGO/ZnO composites with different size of ZnO particles have been fabricated via a one-step facile solvothermal method. The photocatalytic activities of these... The composites of reduced graphene oxide/ZnO (RCO/ZnO) with different particles size of ZnO have been prepared via a facile solvothermal reaction of graphene... |
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| SubjectTerms | Catalysis Chemistry Degradation Exact sciences and technology General and physical chemistry Graphene Interfacial contact Oxides Particulate composites Photocatalysis Photostability Reduced graphene oxide Reduction Semiconductors Size and synergetic effect Surface physical chemistry Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry Zinc oxide ZnO |
| Title | Size effect induced activity enhancement and anti-photocorrosion of reduced graphene oxide/ZnO composites for degradation of organic dyes and reduction of Cr(VI) in water |
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