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首页> 外文期刊>Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics >Fabrication of Fe3O4@graphene/TiO2 nanohybrid with enhanced photocatalytic activity for isopropanol degradation
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Fabrication of Fe3O4@graphene/TiO2 nanohybrid with enhanced photocatalytic activity for isopropanol degradation

机译:具有增强的光催化活性的Fe3O4 @ Graphene / TiO2纳米油脂的制备用于异丙醇降解

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摘要

We report on the fabrication of a Fe3O4@graphene/TiO2 (F@G/TiO2) nanohybrid using a facile two-step hydrothermal method. Compared with either the binary graphene/TiO2 (G/TiO2) or pure TiO2, the ternary F@G/TiO2 nanohybrid exhibited an apparently improved performance for photocatalytic isopropanol (IPA) degradation, and the sample F-1@G/TiO2 (0.4 wt% Fe3O4 and 0.2 wt% graphene) achieved the highest activity (262.5 mmoL/h for acetone evolution; 28.8 mmoL/h for CO2 evolution) under an AM 1.5G solar simulator irradiation. In the F@G/TiO2 nanohybrid, the magnetic field arisen from Fe3O4 and the excellent electrical conductivity of graphene were believed to facilitate the separation and transport of photoinduced electrons and holes in TiO2. As a consequence, the synergetic effect could account for the enhanced photocatalytic activity of F@G/TiO2 nanohybrid. Mechanistic study indicated that O-2(center dot-) and hole were the main reactive oxygen species for photocatalytic IPA degradation. (C) 2019 Elsevier B.V. All rights reserved.
机译:我们用舒适的两步水热法向制备Fe3O4 @ Graphene / TiO2(F @ G / TiO 2)纳米次组的制备。与二元石墨烯/ TiO 2(G / TiO 2)或纯TiO 2相比,三元F @ G / TiO2纳米嗜含量显示出明显提高的光催化异丙醇(IPA)降解的性能,以及样品F-1 @ G / TiO2(0.4在AM 1.5G太阳模拟器辐射下,WT%Fe3O4和0.2wt%的石墨烯(对于丙酮演化为262.5mmol / h,对于二氧化碳演进),实现了最高的活性(262.5mmol / h; CO2进化的28.8mmol / h)。在F @ G / TiO2纳米冬次嗜含量中,据信来自Fe3O4的磁场和石墨烯的优异导电率,以促进TiO 2中光诱导的电子和孔的分离和运输。因此,协同效应可以考虑F @ G / TiO2纳米冬次含量的增强的光催化活性。机械研究表明,O-2(中心点)和孔是光催化IPA降解的主要活性氧。 (c)2019 Elsevier B.v.保留所有权利。

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  • 作者

    Tan Jiahan; Wang Xin; Hou Weishu; Zhang Xueliang; Liu Lequan; Ye Jinhua; Wang Defa;

  • 作者单位

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Adv Ceram &

    Machining Technol Tianjin Key Lab Composite &

    Funct Mat Minist Educ TJU NIMS Int Collaborat Lab Sch Mat Sci &

    Engn 92 Weijin Rd Tianjin 300072 Peoples R China;

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  • 正文语种 eng
  • 中图分类 合金学与各种性质合金;金属材料;
  • 关键词

    Photocatalysis; Fe3O4; Graphene; TiO2; Nanohybrid; Isopropanol degradation;

    机译:光催化;Fe3O4;石墨烯;TiO2;纳米冬次;异丙醇降解;

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