Sintering mechanism and sintering-resistant strategies for metal-based catalyst

被引:0
|
作者
Cao M. [1 ]
Mao Y. [1 ]
Wang Q. [1 ]
Li S. [1 ]
Yan X. [1 ]
机构
[1] College of Chemical Engineering and Technology, Taiyuan University of Technology, Shanxi, Taiyuan
来源
Huagong Jinzhan/Chemical Industry and Engineering Progress | 2023年 / 42卷 / 02期
关键词
catalyst; deactivation; sintering; sintering-resistant strategies;
D O I
10.16085/j.issn.1000-6613.2022-0688
中图分类号
学科分类号
摘要
Metal-based catalysts suffer from sintering of metal particles at high temperature, which causes the decline of catalytic performance and even deactivation. Therefore, improving the thermal stability of metal-based catalysts becomes a critical challenge for heterogeneous catalysis. In this review, the two main sintering mechanisms for metal-based catalyst has elaborated, including particle migration and Ostwald ripening. Four approaches to determine the sintering mechanism by particle size distribution, particle growth kinetics, in situ transmission electron microscopy analysis, and experimental and computational prediction were established. Among them, temperature affects the kinetic energy of metal particle, which is the main physical factor for particle sintering, while chemical potential, as one of the chemical factors for particle sintering, is greatly affected by the metal-support interaction. In addition, we summarized the research progress in developing the sintering-resistant catalysts on the basis of metal-support interaction, spatial confinement and other novel structure strategies. Furthermore, the development and goal for the research and construction of sintering-resistant catalysts are proposed from the aspects of catalyst preparation, structure analysis and catalytic performance. © 2023 Chemical Industry Press. All rights reserved.
引用
下载
收藏
页码:744 / 755
页数:11
相关论文
共 92 条
  • [71] ZHU Qiufeng, ZHANG Qingcheng, WEN Lixiong, Anti-sintering silica-coating CuZnAlZr catalyst for methanol synthesis from CO hydrogenation, Fuel Processing Technology, 156, pp. 280-289, (2017)
  • [72] LU Junling, ELAM J W, STAIR P C., Synthesis and stabilization of supported metal catalysts by atomic layer deposition, Accounts of Chemical Research, 46, 8, pp. 1806-1815, (2013)
  • [73] LU Junling, FU Baosong, KUNG M C, Et al., Coking- and sintering-resistant palladium catalysts achieved through atomic layer deposition, Science, 335, 6073, pp. 1205-1208, (2012)
  • [74] MA Ziran, WANG Baodong, LU Guangjie, Et al., Preparation and performance of SAPO-34 based SCR catalyst derived from fly ash, Chemical Industry and Engineering Progress, 39, 10, pp. 4051-4060, (2020)
  • [75] YU Dongni, DAI Weili, WU Guangjun, Et al., Stabilizing copper species using zeolite for ethanol catalytic dehydrogenation to acetaldehyde, Chinese Journal of Catalysis, 40, 9, pp. 1375-1384, (2019)
  • [76] WANG Shuai, ZHAO Qingfei, WEI Huimin, Et al., Aggregation-free gold nanoparticles in ordered mesoporous carbons: toward highly active and stable heterogeneous catalysts, Journal of the American Chemical Society, 135, 32, pp. 11849-11860, (2013)
  • [77] ISHIHARA D, TAO Kai, YANG Guohui, Et al., Precisely designing bimodal catalyst structure to trap cobalt nanoparticles inside mesopores and its application in Fischer-Tropsch synthesis, Chemical Engineering Journal, 306, pp. 784-790, (2016)
  • [78] ZHANG Xianhua, ZHANG Li, PENG Honggen, Et al., Nickel nanoparticles embedded in mesopores of AlSBA-15 with a perfect peasecod-like structure: A catalyst with superior sintering resistance and hydrothermal stability for methane dry reforming, Applied Catalysis B: Environmental, 224, pp. 488-499, (2018)
  • [79] DING Chuanmin, MA Zili, LI Yufeng, Et al., Preparation of Ni@ZSM-5 catalyst and its reaction performance for partial oxidation of methane, Natural Gas Chemical Industry, 45, 6, pp. 1-6, (2020)
  • [80] Li Hesheng, Application and prospect of metal-organic frameworks in petrochemical industry, Petrochemical Technology, 51, 2, pp. 190-198, (2022)
12345678910