Preparation and application of metal oxides with various morphology for industrial catalysis

doi:10.11949/0438-1157.20210108

Abstract

Abstract:

Metal oxides catalysts have been widely used in a large variety of industrial processes, including ammonia synthesis, energy conversion and fine chemical synthesize. The morphology of metal oxides has an important effect on the catalytic performance. Compared to bulk materials, metal oxides catalysts with specific morphology exhibit unique structure properties in many aspects, which has become a research hotspot in the field of materials science. In this review, we highlight the preparation method, formation mechanism and structural property of metal oxides with various morphology, and their recent progresses in oxidation, steam reforming and hydrogenation are also reviewed. In the final section, future opportunities and challenges in the preparation of metal oxides catalysts are discussed, and some strategies to resolve these critical problems are further proposed.

Key words: various morphology, preparation method, formation mechanism, metal oxide catalysts

摘要：

金属氧化物作为一类重要工业催化剂，广泛应用于合成氨工业、能源化工、精细化工等重要的工业生产过程。金属氧化物的形貌对其性能有重要的影响，具有特定形貌的金属氧化物催化剂因其结构上的优势，使其在许多方面表现出不同于常规块体材料的独特性能，成为当前材料科学领域的研究热点。本文总结了不同形貌的金属氧化物的制备方法、生长机制及其结构特性，聚焦于金属氧化物在氧化反应、加氢反应以及蒸汽重整反应中的最新研究进展。最后，进一步讨论了金属氧化物催化剂未来的发展趋势以及面临的挑战，并提出了解决这些问题的有效方案。

关键词: 不同形貌, 制备方法, 生长机制, 金属氧化物催化剂

CLC Number:

TQ 201

ZHOU Shijie, REN Zhen, YANG Yusen, WEI Min. Preparation and application of metal oxides with various morphology for industrial catalysis[J]. CIESC Journal, 2021, 72(6): 2972-3001.

周石杰, 任祯, 杨宇森, 卫敏. 不同形貌金属氧化物的制备及其在工业催化反应中的应用[J]. 化工学报, 2021, 72(6): 2972-3001.

Figures/Tables 15

Fig.1 FE-SEM images of the precursors synthesized at 160℃ for 2 h (a), 3 h (b), 4 h (c), 5 h (d), 6 h (e)[48]

Fig.2 Evolution process of the family of multishelled ZnO hollow microspheres. Transmission electron microscopy images of carbonaceous microspheres after immersion in zinc nitrate solutions before heating (room temperature) and after heating at different temperatures (400℃, 400℃ for 30 min, 420℃, 440℃, 460℃, 480℃ and 500℃). 3 and 5 mol/L zinc nitrate solutions were used in samples Ⅰ, Ⅱ, Ⅲ and samples Ⅳ, Ⅴ, Ⅵ, Ⅶ, Ⅷ, Ⅸ, respectively. The diameters of carbonaceous microspheres used in samples Ⅰ, Ⅱ, Ⅲ, Ⅳ, Ⅴ and Ⅵ are 3 μm, and those used in samples Ⅶ, Ⅷ, and Ⅸ are 4 μm. The temperature in the fast and medium heating modes is directly increased to 500℃ at 2 and 1℃/min respectively, while the temperature in the slow heating mode is increased to 500℃ at 1℃/minwith 30 min holding at 400℃. The scale bars are 1 μm for the samples from Ⅰ to Ⅵ and 1.3 μm for samples from Ⅶ to Ⅸ in the first column. All the scale bars in the second column are 0.5 μm, while the scale bars in the third and higher columns are all 0.3 μm(a). Illustration of the formation of multishelled ZnO hollow microspheres through different heating processes(b) [57]

Fig.3 SEM images of the three types of calcined Co3O4 and their structure models: Co3O4 cubes[(a)~(c)], Co3O4 truncated octahedra[(d)—(f)], and Co3O4 octahedra[(g)—(i)] [58]

Fig.4 Schematic illustration of the formation of the precursor FeOOH[62]

Fig.5 Time-dependent evolution of ZnO nanocrystals to ZnO hollow spheres with double-yolk egg structure: 1 h (a), 12 h (b), 24 h (c). The corresponding schematic graphs of the evolution process (d) [64]

Fig.6 Overall flowchart for fabrication of BHC-TiO2[(a)—(d)]; Corresponding FESEM[(e)—(h)], BSE-SEM [(i)—(l)] and TEM images[(m)—(p)] of the BHC-TiO2 fabrication procedure. The white arrows indicate the cracked hollow cubic structures. The scale bars are 1 μm [(e)—(h)] and 500 nm[(i)—(p)][66]

Fig.7 Schematic illustration of the process of MIL-53(Fe) growth and morphology of their corresponding iron oxides (a) and the formation process of Fe2O3-2 and Fe2O3-6 (b) [67]

Fig.8 SEM pictures of ZnO crystals grown under laser power density of 9.55 kW/cm2 (a), 15.92 kW/cm2 (b), 22.29 kW/cm2 (c), 28.66 kW/cm2 (d) in 200 kHz for 5 min. Schematic illustration of crystal growth in kinetically controlled (left direction) and thermodynamically controlled (right direction) processes (e). All scale bars represent 500 nm in length[68]

Fig.9 Effect of Tdep on TC(220), (311), (111), (400) and (511) of Co3O4 films (a), growth mechanism of (111) planes (b), enlarged FESEM image (c) and schematic of nanowall structure of Co3O4 film prepared at 773 K(d) [69]

Fig.10 SEM and TEM images of samples prepared at different temperatures: S-600[(a),(b)], S-750[(c),(d)], S-850[(e),(f)] and S-950[(g),(h)][70]

Fig.11 Additional Ce3+ sites derived from high-temperature reduction favoring adsorption of the reactant and intermediate[75]

Fig.12 TEM and high-resolution TEM (HRTEM) images of CeO2-R[(a)，(b)], CeO2-P[(c)，(d)], CeO2-C[(e)，(f)], SEM(g) and HRTEM(h) images of CeO2-O. The insets schematically illustrate the crystal planes exposed on the CeO2-R, CeO2-P, CeO2-C and CeO2-O[78]

Fig.13 Schematic CO oxidation pathways catalyzed by Au/CeO2(100) (a) and Au/CeO2(111) (b) with 8 or 4 adsorbed CO molecules show that CO oxidation occurs at the Au-CeO2 interface, although an additional O—C—O formation step [(b), step②] is required for Au/CeO2(111) [86]

Fig.14 TEM images [(ⅰ),(ⅱ)], HRTEM image (ⅲ), IFFT image (ⅳ) of the α-Fe2O3-THB sample(a). TEM images [(ⅰ),(ⅱ)], HRTEM image (ⅲ), IFFT image (ⅳ) of α-Fe2O3-QC sample (b). TEM image (ⅰ), SAED pattern (ⅱ), and schematic illustration (ⅲ) of α-Fe2O3-HS sample(c)[87]

Fig.15 CO selectivity of Pd/ZnO-N (a) and Pd/ZnO-P (b) with Pd loading amount under methanol conversion of 30%—40% [88]

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