Modeling Semi-Batch Vinyl Acetate Polymerization Processes

Feuerpfeil, Andreas; Drache, Marco; Jantke, Laura‐Alice; Melchin, Timo; Rodrı́guez-Fernández, Jessica; Beuermann, Sabine

doi:10.1021/acs.iecr.1c03114

Cited by 9 publications

(9 citation statements)

References 72 publications

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“…[ 2 ] To estimate the missing rate coefficients experimental polymerization results are compared to in‐silico derived data by Monte Carlo simulation and the Metropolis–Hastings algorithm is applied for parameterization. [ 50 ] The kinetic model is given in Scheme and the associated kinetic rate coefficients are listed in Table 1 . The complete set of elemental reactions required for kMC simulation of the self‐initiated polymerization of BA in bulk and solution comprises 50 elemental reactions.…”

Section: Resultsmentioning

confidence: 99%

“…The automated parameter search was executed by a Metropolis Hastings algorithm, which has already been used before. [50] A detailed description of the strategy is provided by Feuerpfeil et al [50] Table 1. Full set of kinetic coefficients used in kMC simulations.…”

Section: Determination Of the Transfer Coefficient To Solvent K Trsmentioning

confidence: 99%

“…Previously, the simulator was successfully applied to model, for example, butyl acrylate polymerizations, seeded emulsion polymerizations of styrene or reversible deactivation radical polymerization. [34,39,50,51] Additional details of the simulator were provided elsewhere. [52]…”

Section: Software For Kinetic Monte Carlo Simulationsmentioning

confidence: 99%

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Kinetic Monte Carlo Simulations as a Tool for Unraveling the Impact of Solvent and Temperature on Polymer Topology for Self‐Initiated Butyl Acrylate Radical Polymerizations at High Temperatures

Mätzig

Drache

Drache³

et al. 2023

Macro Theory & Simulations

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High‐temperature butyl acrylate polymerizations in bulk and in solution are investigated experimentally and by kinetic Monte Carlo (kMC) simulations. The experimental data comprise conversion‐time data, molar mass distributions, and branching levels per polymer chain derived from size‐exclusion chromatography with a multiangle laser light scattering detector. A kMC model is established, which allows for the description of the impact of solvent and temperature on molar mass distribution as well as type and content of macromonomers. Within the study kinetic coefficients for transfer to solvent and the thermal self‐initiation of the monomer are determined according to the Metropolis Hastings algorithm. The kMC simulations provide information, which are otherwise not accessible, for example, the number of branch points per molecule as a function of molar mass or the molar mass distribution of various macromonomer species. Moreover, molar ratios of mid‐chain and chain‐end radicals are at hand for temperatures up to 160°C, which are important for the interpretation of the experimentally and via simulation‐derived polymer topology as a function of molar masses.

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Section: Resultsmentioning

confidence: 99%

Section: Determination Of the Transfer Coefficient To Solvent K Trsmentioning

confidence: 99%

See 1 more Smart Citation

Kinetic Monte Carlo Simulations as a Tool for Unraveling the Impact of Solvent and Temperature on Polymer Topology for Self‐Initiated Butyl Acrylate Radical Polymerizations at High Temperatures

Mätzig

Drache

Drache³

et al. 2023

Macro Theory & Simulations

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“…Since then improvement in computing power and coding allowed for the application of the algorithm to more and more complex systems (Trigilio, Marien, van The kMC simulations were conducted using the in-house created open source kMC simulator mcPolymer (Drache & Drache, 2012), which is based on a full kinetic scheme with all elemental reactions occurring. Previously, the simulator was successfully applied to model, e.g., reversible deactivation radical polymerizations (Drache, 2009;Drache & Drache, 2012), acrylate polymerizations with backbiting and transfer to polymer reactions (Drache et al, 2015), or semi-batch vinyl acetate polymerization (Feuerpfeil et al, 2021).…”

Section: Kmc Simulationmentioning

confidence: 99%

Polymer Reaction Engineering meets Explainable Machine Learning

Fiošina

Sievers

Drache

et al. 2023

Preprint

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Due to the complicated polymerization technique and statistical composition of the polymer, tailoring its characteristics is a challenging task. Modeling of the polymerizations can contribute to deeper insights into the process. This study applies state-of-the-art machine learning (ML) methods for modeling and reverse engineering of polymerization processes. ML methods (random forest, XGBoost and CatBoost) are trained on data sets generated by an in house developed kinetic Monte Carlo simulator. The applied ML models predict monomer concentration, average molar masses and full molar mass distributions with excellent accuracy (R2 > 0.96). Reverse engineering results delivering the polymerization recipe for a targeted molar mass distribution are less accurate, but still only minor deviations from the targeted molar mass distribution are seen. The influences of the input variables in ML models obtained by explainability methods correspond to the expert expectations.

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“…The model-based regression analysis from kinetic data, as an alternative computational approach, enables researchers to calculate the intrinsic/apparent rate coefficients in FRP (Figure b). − The method includes deterministic and stochastic-based approaches. − The former is achieved through solving a set of algebraic/differential equations derived from mass balances, while the latter only requires the reaction probabilities . The method of moments (MoM) − and kinetic Monte Carlo ( k MC) − are the two most widely used kinetic modeling methods. More recently, Wu et al developed the distribution–numerical fractionation–method of moments (D–NF–MoM) model, which is capable of predicting bivariate distributions of macrospecies and bring the MoM deterministic solver a step forward .…”

Section: Introductionmentioning

confidence: 99%

Quantitative Structure–Property Relationship Model for Predicting the Propagation Rate Coefficient in Free-Radical Polymerization

Shi

Liu

et al. 2022

Macromolecules

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In this work, a generalized quantitative structure–property relationship (QSPR) model is developed for predicting k p by using norm index (NI)-based descriptors, which is the so-called k p (T, NI)-QSPR model. The as-developed model enables the use of one unified formula to calculate k p values for a wide range of monomers, including linear and branched (meth)acrylates, nitrogen-containing methacrylates, hydroxyl-containing (meth)acrylates, and so forth. Importantly, the model exhibits excellent performance when compared with the benchmark k p values from the literature, and model validation proves the reasonable goodness-of-fit, robustness, predictivity, and reliability of the as-developed model. Meanwhile, the Arrhenius parameters show a clear kinetic behavior, indicating that acrylates have smaller fit, robustness, predictivity, and reliability of the as-developed model. Meanwhile, the Arrhenius parameters show a clear kinetic behavior, indicating that acrylates have smaller E a values than methacrylates, which render higher k p values and activities in free-radical polymerization for acrylates. Notably, the model allows the prediction of k p values of monomer mixtures and new monomers. In view of the satisfactory accuracy in determining k p values, it is expected that our proposed method will contribute to the determination of kinetic parameters beyond propagation kinetics for a wide monomer range, and the obtained Arrhenius parameters can further improve the fundamental understanding of radical polymerization kinetics.

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Modeling Semi-Batch Vinyl Acetate Polymerization Processes

Cited by 9 publications

References 72 publications

Kinetic Monte Carlo Simulations as a Tool for Unraveling the Impact of Solvent and Temperature on Polymer Topology for Self‐Initiated Butyl Acrylate Radical Polymerizations at High Temperatures

Kinetic Monte Carlo Simulations as a Tool for Unraveling the Impact of Solvent and Temperature on Polymer Topology for Self‐Initiated Butyl Acrylate Radical Polymerizations at High Temperatures

Polymer Reaction Engineering meets Explainable Machine Learning

Quantitative Structure–Property Relationship Model for Predicting the Propagation Rate Coefficient in Free-Radical Polymerization

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