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Single catalyst particle growth modeling in thermocatalytic decomposition of methane

M. Hadian, K. A. Buist, René Bos (UGent) and J. A. M. Kuipers
(2021) CHEMICAL ENGINEERING JOURNAL. 421(Part 1).
Author
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Abstract
ThermoCatalytic Decomposition of methane (TCD) is studied as a method to convert natural gas into hydrogen and functional carbon. In these processes the carbon typically formed on top of a catalyst phase leading to particle growth. Therefore, the development of a particle growth model is necessary to understand the limitations of thermocatalytic decomposition of methane and to assess optimal parameters and process conditions. In this paper, a particle growth model is presented to describe the growth of functional carbon on the catalyst particle. This coupled model requires kinetic equations and information on deactivation rates which have been studied from literature. The morphology of the particle changes due to carbon formation, which leads to eventual deactivation. Therefore, these kinetic expressions are coupled to a particle growth model based on the analogy with the growth of particles in polyolefin production. To combine the effects of particle growth, kinetics, and internal heat and mass transfer, the Multi-Grain Model (MGM) was used. Results confirm that with the currently available catalysts the carbon yield is not affected by heat and mass transfer limitations, however, with the availability of more active catalysts these limitations will become important. Temperature, however, has a significant role in that it regulates the kinetic rate and thus growth rate, which in turn influences the catalyst deactivation. The optimum temperature for the production of nano-carbon, within a reasonable process time, therefore sensitively depends on the choice of catalyst.
Keywords
Industrial and Manufacturing Engineering, General Chemistry, General Chemical Engineering, Environmental Chemistry, Multi-grain model, Thermocatalytic decomposition of methane, Particle growth, Deactivation, PROPYLENE POLYMERIZATION, MOLECULAR-DYNAMICS, FREE HYDROGEN, CARBON, FRAGMENTATION, NANOCARBON, DEPOSITION, KINETICS, ALUMINA

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MLA
Hadian, M., et al. “Single Catalyst Particle Growth Modeling in Thermocatalytic Decomposition of Methane.” CHEMICAL ENGINEERING JOURNAL, vol. 421, no. Part 1, 2021, doi:10.1016/j.cej.2021.129759.
APA
Hadian, M., Buist, K. A., Bos, R., & Kuipers, J. A. M. (2021). Single catalyst particle growth modeling in thermocatalytic decomposition of methane. CHEMICAL ENGINEERING JOURNAL, 421(Part 1). https://doi.org/10.1016/j.cej.2021.129759
Chicago author-date
Hadian, M., K. A. Buist, René Bos, and J. A. M. Kuipers. 2021. “Single Catalyst Particle Growth Modeling in Thermocatalytic Decomposition of Methane.” CHEMICAL ENGINEERING JOURNAL 421 (Part 1). https://doi.org/10.1016/j.cej.2021.129759.
Chicago author-date (all authors)
Hadian, M., K. A. Buist, René Bos, and J. A. M. Kuipers. 2021. “Single Catalyst Particle Growth Modeling in Thermocatalytic Decomposition of Methane.” CHEMICAL ENGINEERING JOURNAL 421 (Part 1). doi:10.1016/j.cej.2021.129759.
Vancouver
1.
Hadian M, Buist KA, Bos R, Kuipers JAM. Single catalyst particle growth modeling in thermocatalytic decomposition of methane. CHEMICAL ENGINEERING JOURNAL. 2021;421(Part 1).
IEEE
[1]
M. Hadian, K. A. Buist, R. Bos, and J. A. M. Kuipers, “Single catalyst particle growth modeling in thermocatalytic decomposition of methane,” CHEMICAL ENGINEERING JOURNAL, vol. 421, no. Part 1, 2021.
@article{8706838,
  abstract     = {{ThermoCatalytic Decomposition of methane (TCD) is studied as a method to convert natural gas into hydrogen and functional carbon. In these processes the carbon typically formed on top of a catalyst phase leading to particle growth. Therefore, the development of a particle growth model is necessary to understand the limitations of thermocatalytic decomposition of methane and to assess optimal parameters and process conditions. In this paper, a particle growth model is presented to describe the growth of functional carbon on the catalyst particle. This coupled model requires kinetic equations and information on deactivation rates which have been studied from literature. The morphology of the particle changes due to carbon formation, which leads to eventual deactivation. Therefore, these kinetic expressions are coupled to a particle growth model based on the analogy with the growth of particles in polyolefin production. To combine the effects of particle growth, kinetics, and internal heat and mass transfer, the Multi-Grain Model (MGM) was used. Results confirm that with the currently available catalysts the carbon yield is not affected by heat and mass transfer limitations, however, with the availability of more active catalysts these limitations will become important. Temperature, however, has a significant role in that it regulates the kinetic rate and thus growth rate, which in turn influences the catalyst deactivation. The optimum temperature for the production of nano-carbon, within a reasonable process time, therefore sensitively depends on the choice of catalyst.}},
  articleno    = {{129759}},
  author       = {{Hadian, M. and Buist, K. A. and Bos, René and Kuipers, J. A. M.}},
  issn         = {{1385-8947}},
  journal      = {{CHEMICAL ENGINEERING JOURNAL}},
  keywords     = {{Industrial and Manufacturing Engineering,General Chemistry,General Chemical Engineering,Environmental Chemistry,Multi-grain model,Thermocatalytic decomposition of methane,Particle growth,Deactivation,PROPYLENE POLYMERIZATION,MOLECULAR-DYNAMICS,FREE HYDROGEN,CARBON,FRAGMENTATION,NANOCARBON,DEPOSITION,KINETICS,ALUMINA}},
  language     = {{eng}},
  number       = {{Part 1}},
  pages        = {{9}},
  title        = {{Single catalyst particle growth modeling in thermocatalytic decomposition of methane}},
  url          = {{http://doi.org/10.1016/j.cej.2021.129759}},
  volume       = {{421}},
  year         = {{2021}},
}
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