1D-Co3O4, 2D-Co3O4, 3D-Co3O4 for catalytic oxidation of toluene

[Display omitted] •1D-Co3O4 nanoneedle, 2D-Co3O4 nanoplate, and 3D-Co3O4 nanoflower were synthesized.•3D-Co3O4 nanoflower exhibits the excellent activity toward toluene oxidation.•The low-temperature reducibility, Oads/Olatt, and Co3+/Co2+ are crucial.•3D-Co3O4 nanoflower showed good stability for t...

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Bibliographic Details
Published in:Catalysis today 2019-07, Vol.332, p.160-167
Main Authors: Ren, Quanming, Feng, Zhentao, Mo, Shengpeng, Huang, Chunlei, Li, Shujun, Zhang, Weixia, Chen, Limin, Fu, Mingli, Wu, Junliang, Ye, Daiqi
Format: Article
Language:English
Subjects:
Catalytic oxidation
Co3O4
Morphologies
Nanomaterials
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Summary:[Display omitted] •1D-Co3O4 nanoneedle, 2D-Co3O4 nanoplate, and 3D-Co3O4 nanoflower were synthesized.•3D-Co3O4 nanoflower exhibits the excellent activity toward toluene oxidation.•The low-temperature reducibility, Oads/Olatt, and Co3+/Co2+ are crucial.•3D-Co3O4 nanoflower showed good stability for toluene catalytic oxidation. A facile template-free hydrothermal method was applied to successfully synthesize a series of bulk cobalt oxides with different morphologies (1D-Co3O4 nanoneedle, 2D-Co3O4 nanoplate, and 3D-Co3O4 nanoflower). The catalytic activity for the toluene combustion over various types of catalysts was investigated. The 3D-Co3O4 nanoflower performed the excellent activity and the temperature required for achieving a toluene conversion of 90 % (T90%) at approximately 238 °C with the activity energy (Ea) of 71.6 KJ mol−1, which was 19 ℃ lower than that of 1D-Co3O4 nanoneedle with Ea of 97.1 KJ mol−1 at a space velocity (WHSV = 48, 000 mL g−1  h−1). The effect of shape on the physicochemical properties of the Co3O4 catalysts were characterized by various analytical techniques. It has been found that large specific surface area, low temperature reducibility, highly defective structure with abundant surface active oxygen species and rich Co3+ cationic species were responsible for the excellent catalytic performance of 3D-Co3O4 nanoflower. In addition, complete conversion of toluene had remained the same after 3D-Co3O4 nanoflower was observed for 120 h, suggesting it exhibited the long-term stability for toluene combustion. Therefore, 3D-Co3O4 nanoflower might be a potential non-noble catalyst in practical application.
ISSN:0920-5861
1873-4308
DOI:10.1016/j.cattod.2018.06.053