Multiscale modeling of a free-radical emulsion polymerization process: Numerical approximation by the Finite Element Method

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Authors

  • Jorge Humberto Urrea-Quintero
  • Michele Marino
  • Hugo Hernandez
  • Silvia Ochoa

Research Organisations

External Research Organisations

  • Universidad de Antioquia
  • Tor Vergata University of Rome
  • ForsChem Research
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Details

Original languageEnglish
Article number106974
JournalComputers and Chemical Engineering
Volume140
Early online date16 Jun 2020
Publication statusPublished - 2 Sept 2020

Abstract

A multiscale modeling description of free-radical polymerization processes is presented. The polymerization process is described at the macroscale by coupling the Fokker-Planck Equation (FPE) for the particle size distribution (PSD) prediction at the mesoscale with a kinetic Monte Carlo (kMC) simulation at the microscale. The finite element method is adopted to solve the mesoscopic scale to capture the nonlinear evolution of the PSD, successfully facing challenges related to accuracy and computational cost in the FPE numerical solution. Additionally, the proposed model captures the evolution of the average number of free-radicals and secondary nucleation rate at the microscopic level. The control of the secondary nucleation rate is in fact critical to satisfactorily obtain high quality structured polymer particles. Finally, a closed-form model is developed at the microscopic scale to handle the curse of dimensionality. Simulations to evaluate the capabilities of the proposed numerical scheme and sensitivity analyses with respect to the system inputs and uncertainties in the initial condition of the PSD are performed.

Keywords

    Finite Element Method, Fokker-Planck equation, Free-radical polymerization, kMC, PDE/ODEs-kMC multiscale systems, Statistical modeling

ASJC Scopus subject areas

Cite this

Multiscale modeling of a free-radical emulsion polymerization process: Numerical approximation by the Finite Element Method. / Urrea-Quintero, Jorge Humberto; Marino, Michele; Hernandez, Hugo et al.
In: Computers and Chemical Engineering, Vol. 140, 106974, 02.09.2020.

Research output: Contribution to journalArticleResearchpeer review

Urrea-Quintero JH, Marino M, Hernandez H, Ochoa S. Multiscale modeling of a free-radical emulsion polymerization process: Numerical approximation by the Finite Element Method. Computers and Chemical Engineering. 2020 Sept 2;140:106974. Epub 2020 Jun 16. doi: 10.1016/j.compchemeng.2020.106974
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title = "Multiscale modeling of a free-radical emulsion polymerization process: Numerical approximation by the Finite Element Method",
abstract = "A multiscale modeling description of free-radical polymerization processes is presented. The polymerization process is described at the macroscale by coupling the Fokker-Planck Equation (FPE) for the particle size distribution (PSD) prediction at the mesoscale with a kinetic Monte Carlo (kMC) simulation at the microscale. The finite element method is adopted to solve the mesoscopic scale to capture the nonlinear evolution of the PSD, successfully facing challenges related to accuracy and computational cost in the FPE numerical solution. Additionally, the proposed model captures the evolution of the average number of free-radicals and secondary nucleation rate at the microscopic level. The control of the secondary nucleation rate is in fact critical to satisfactorily obtain high quality structured polymer particles. Finally, a closed-form model is developed at the microscopic scale to handle the curse of dimensionality. Simulations to evaluate the capabilities of the proposed numerical scheme and sensitivity analyses with respect to the system inputs and uncertainties in the initial condition of the PSD are performed.",
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N1 - Funding Information: We thank the anonymous reviewers of this work for their valuable comments and suggestions that helped improving the quality of this manuscript. Jorge-Humberto Urrea-Quintero gratefully acknowledges COLCIENCIAS for the financial support via the Doctoral Scholarship 727–2015 granted. Lkewise, the gratitude is extended to the Institute of Continuum Mechanics - IKM at Leibniz Universität Hannover, Germany, for hosting him as visiting researcher. Particularly, to Prof. Dr.-Ing. habil. Dr. h.c. mult. Dr.-Ing. E. h. Peter Wriggers for the financial support provided during the internship period at IKM. M. Marino acknowledges that this work has been carried out within the framework of the SMART BIOTECS alliance between the Technical University of Braunschweig and the Leibniz University of Hannover (Ministry of Science and Culture of Lower Saxony, Germany) and to the program “Rita Levi Montalcini” for young researchers (Ministry of Education, University and Research, Italy).

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