Self-Assembly Fabrication of Hollow Mesoporous Silica@Co–Al Layered Double Hydroxide@Graphene and Application in Toxic Effluents Elimination

Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co–Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and...

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Published in	ACS applied materials & interfaces Vol. 7; no. 16; pp. 8506 - 8514
Main Authors	Jiang, Shu-Dong, Song, Lei, Zeng, Wen-Ru, Huang, Zheng-Qi, Zhan, Jing, Stec, Anna A, Hull, T. Richard, Hu, Yuan, Hu, Wei-Zhao
Format	Journal Article
Language	English
Published	United States American Chemical Society 29.04.2015
Subjects	chemical reduction coatings combustion effluents epoxides graphene graphene oxide porous media silica toxicity volatile organic compounds composites self-assembly fire effluents elimination mechanism HM-SiO2@Co−Al LDH@graphene epoxy
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Abstract	Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co–Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and chemical reduction. As a result of the electrostatic potential difference among HM-SiO2, Co–Al LDH, and graphene oxide, the HM-SiO2 spheres were coated by Co–Al LDH and graphene. Subsequently, the HM-SiO2@Co–Al LDH@graphene spheres were introduced into an epoxy resin (EP) matrix for investigation of their toxic effluents capture and elimination effectiveness during combustion. The amount of toxic CO and volatile organic compounds from the epoxy resin decomposition significantly suppressed after incorporating the HM-SiO2@Co–Al LDH@graphene hybrids, implying a reduced toxicity.
AbstractList	Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co-Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and chemical reduction. As a result of the electrostatic potential difference among HM-SiO2, Co-Al LDH, and graphene oxide, the HM-SiO2 spheres were coated by Co-Al LDH and graphene. Subsequently, the HM-SiO2@Co-Al LDH@graphene spheres were introduced into an epoxy resin (EP) matrix for investigation of their toxic effluents capture and elimination effectiveness during combustion. The amount of toxic CO and volatile organic compounds from the epoxy resin decomposition significantly suppressed after incorporating the HM-SiO2@Co-Al LDH@graphene hybrids, implying a reduced toxicity. Here, we propose a self-assembly process to prepare hierarchical HM-SiO₂@Co–Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and chemical reduction. As a result of the electrostatic potential difference among HM-SiO₂, Co–Al LDH, and graphene oxide, the HM-SiO₂ spheres were coated by Co–Al LDH and graphene. Subsequently, the HM-SiO₂@Co–Al LDH@graphene spheres were introduced into an epoxy resin (EP) matrix for investigation of their toxic effluents capture and elimination effectiveness during combustion. The amount of toxic CO and volatile organic compounds from the epoxy resin decomposition significantly suppressed after incorporating the HM-SiO₂@Co–Al LDH@graphene hybrids, implying a reduced toxicity. Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co-Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and chemical reduction. As a result of the electrostatic potential difference among HM-SiO2, Co-Al LDH, and graphene oxide, the HM-SiO2 spheres were coated by Co-Al LDH and graphene. Subsequently, the HM-SiO2@Co-Al LDH@graphene spheres were introduced into an epoxy resin (EP) matrix for investigation of their toxic effluents capture and elimination effectiveness during combustion. The amount of toxic CO and volatile organic compounds from the epoxy resin decomposition significantly suppressed after incorporating the HM-SiO2@Co-Al LDH@graphene hybrids, implying a reduced toxicity.Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co-Al LDH@graphene, with the purpose of combining their outstanding performance. Hollow mesoporous silica was first synthesized as the core, using a novel sonochemical method, followed by a controlled shell coating process and chemical reduction. As a result of the electrostatic potential difference among HM-SiO2, Co-Al LDH, and graphene oxide, the HM-SiO2 spheres were coated by Co-Al LDH and graphene. Subsequently, the HM-SiO2@Co-Al LDH@graphene spheres were introduced into an epoxy resin (EP) matrix for investigation of their toxic effluents capture and elimination effectiveness during combustion. The amount of toxic CO and volatile organic compounds from the epoxy resin decomposition significantly suppressed after incorporating the HM-SiO2@Co-Al LDH@graphene hybrids, implying a reduced toxicity.
Author	Zeng, Wen-Ru Huang, Zheng-Qi Stec, Anna A Song, Lei Hu, Wei-Zhao Hu, Yuan Jiang, Shu-Dong Hull, T. Richard Zhan, Jing
AuthorAffiliation	University of Science and Technology of China Suzhou Key Laboratory of Urban Public Safety, Suzhou Institute for Advanced Study University of Central Lancashire State Key Laboratory of Fire Science Centre for Fire and Hazards Science
AuthorAffiliation_xml	– name: University of Science and Technology of China – name: Suzhou Key Laboratory of Urban Public Safety, Suzhou Institute for Advanced Study – name: Centre for Fire and Hazards Science – name: State Key Laboratory of Fire Science – name: University of Central Lancashire
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Snippet	Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co–Al LDH@graphene, with the purpose of combining their outstanding performance.... Here, we propose a self-assembly process to prepare hierarchical HM-SiO2@Co-Al LDH@graphene, with the purpose of combining their outstanding performance.... Here, we propose a self-assembly process to prepare hierarchical HM-SiO₂@Co–Al LDH@graphene, with the purpose of combining their outstanding performance....
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SubjectTerms	chemical reduction coatings combustion effluents epoxides graphene graphene oxide porous media silica toxicity volatile organic compounds
Title	Self-Assembly Fabrication of Hollow Mesoporous Silica@Co–Al Layered Double Hydroxide@Graphene and Application in Toxic Effluents Elimination
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