Parameter Estimation and Kinetic Monte Carlo Simulation of Styrene and <i>n</i>-Butyl Acrylate Copolymerization through ATRP

Rego, Artur S. C.; Brandão, Amanda L. T.

doi:10.1021/acs.iecr.1c00943

Cited by 13 publications

(11 citation statements)

References 81 publications

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“…[20,21] The use of simulation models to study polymerization reactions has also developed over the last decade. [22][23][24] When coupled to external electric field control, the complexity of the reaction is intensified. From an operational point of view, this has been addressed through the development of simplified electrochemical atom transfer radical polymerization (seATRP) [25] which employs sacrificial electrodes to enable 3-electrode (potential controlled) or 2-electrode (current controlled) configurations in undivided electrochemical cells.…”

Section: Introductionmentioning

confidence: 99%

Active Learning as a Tool for Optimizing “Plug‐n‐Play” Electrochemical Atom Transfer Radical Polymerization

Zhao

Cheng

Gao

et al. 2023

Macro Chemistry & Physics

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A recently reported “plug‐n‐play” approach to simplified electrochemical atom transfer radical polymerization (seATRP) is investigated using machine learning. It is shown that Bayesian optimization via an active learning (AL) algorithm accelerates optimization of the polymerization of oligo(ethylene glycol methyl ether acrylate)480 (OEGA480) in water. Molecular weight distribution (Mw/Mn; dispersity; Ɖm) is the output selected for optimization targeting poly(oligo[ethylene glycol methyl ether acrylate]) (POEGA480) with low dispersity (Ɖm < 1.30). Input variables included applied potential (Eapp), [M] and [M]/[I], which led to a potential space of 275 possible reaction conditions. From a training data set of seven reactions, selected to yield uncontrolled POEGA480 with higher dispersities (Ɖm > 1.5), ten iteration loops are performed. During each iteration the algorithm suggests the next reaction conditions. The reactions are then performed and the conversion, number average molecular weight (Mn) and Ɖm values are recorded and the Ɖm values fed back into the algorithm. Overall, 80% of the experiments yield POEGA with Ɖm < 1.30. Conversely, only 30% of experiments performed using reaction conditions selected at random from the possible reaction space yield POEGA with Ɖm < 1.30. This study suggests that adopting AL methods can improve the efficiency of optimizing a given seATRP reaction.

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Section: Introductionmentioning

confidence: 99%

Active Learning as a Tool for Optimizing “Plug‐n‐Play” Electrochemical Atom Transfer Radical Polymerization

Zhao

Cheng

Gao

et al. 2023

Macro Chemistry & Physics

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“…In the recent years, there has been a growing interest in better understanding the polymer microstructure using stochastic or kinetic Monte Carlo modeling-based approaches. − There have been several models that provide the chain length distribution for given set of parameters related to a polymerization process, whether it may be for modeling (co)polymerization kinetics, surface-initiated polymerizations (SIP), , or radical-based polymerization processes. − Though these simulations provide a better understanding of the effect of synthesis conditions on the polymer microstructure, they provide no perspective when it comes to complex polymers like architecture-controlled bottlebrush polymers.…”

Section: Introductionmentioning

confidence: 99%

Precision of Architecture-Controlled Bottlebrush Polymer Synthesis: A Monte Carlo Analysis

2022

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Bottlebrush polymers are large macromolecules with a high density of brushes grafted onto a central backbone.Recent experimental work has seen the expansion of these polymer architectures beyond cylinders. Herein we develop a Monte Carlo (MC) method to explore the precision with which these noncylindrical materials can be produced and look to generate design rules for the synthesis of these materials. The computational method captures the stochasticity of the polymerization methods and generates large ensembles of bottlebrush polymers using various synthetic parameters like brush dispersity, backbone dispersity, and rate of polymerization. For each of the cases studied, three independent descriptors (two of them describing the geometrical aspect of the macromolecules and one for the variance in brush lengths) were evaluated. The method highlights the varying tolerance of brush conversion as a function of the target bottlebrush architecture and a need for the low brush (<1.2) and narrow backbone dispersity to get the highest precision in architecture control of bottlebrush polymers. Furthermore, the MC method is utilized to draw comparisons between different methodologies for architecture control. The visualization developed using the Monte Carlo method provides a new way to characterize the precision of architecture-controlled bottlebrush polymer synthesis that is complementary to traditional characterization techniques.

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“…[35] First developed by Gillespie in the context of well-mixed gas phase chemical reactions, kMC has since been applied to systems ranging from vacancy diffusion to thin film growth to free radical polymerization. [35][36][37][38][39][40][41][42][43][44] A fundamental assumption of kMC is that the system is well-mixed, which is most likely to be violated by polymer entanglement at high molecular weight. [36,41] That is, in the limit of very high conversion, the process may no longer be kinetically limited and therefore the predictions of the kinetic model may need to be coupled with a model of physical phenomena like diffusion to be accurate.…”

Section: Introductionmentioning

confidence: 99%

“…[35][36][37][38][39][40][41][42][43][44] A fundamental assumption of kMC is that the system is well-mixed, which is most likely to be violated by polymer entanglement at high molecular weight. [36,41] That is, in the limit of very high conversion, the process may no longer be kinetically limited and therefore the predictions of the kinetic model may need to be coupled with a model of physical phenomena like diffusion to be accurate. Nonetheless, kMC has been demonstrated to accurately predict polymerization and depolymerization results.…”

Section: Introductionmentioning

confidence: 99%

“…Nonetheless, kMC has been demonstrated to accurately predict polymerization and depolymerization results. [41,45,46] Here, we develop a robust, tunable kinetic Monte Carlo framework that tracks the explicit sequences, i.e., not just the average sequence lengths, of the polymer chains during polymerization, enabling straightforward access to sequences, for arbitrary combinations of monomers and reaction conditions. With this approach, we may specify unequal reactivity of different monomers, time variable feed composition, additional side reactions, or reverse reactions.…”

Section: Introductionmentioning

confidence: 99%

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Kinetic Monte Carlo Tool for Kinetic Modeling of Linear Step‐Growth Polymerization: Insight into Recycling of Polyurethanes

Coile

Harmon

Wang

et al. 2021

Macro Theory & Simulations

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A kinetic Monte Carlo model of polyurethane polymerization which explicitly tracks the polymer sequences is developed and shared. This model is benchmarked against theoretical and experimental polyurethane data and used to investigate the effect on oligomer distributions of unequal reactivity of the first and second isocyanate to react. The reverse reactions using thermodynamic consistency are then added to the framework, and analogous to the addition polymerization concept of ceiling temperature, equilibrium chain length distributions at various temperatures are calculated. For a mixture of three monomers AA, BB, and CC, where BB and CC do not react with one another, are present in stoichiometric proportions, and have different enthalpies of reaction with AA, an odd-even effect emerges. Odd length chains are more likely than even length chains for temperatures at which BB and CC have significantly different equilibrium conversions. The concept of ceiling temperature that is typically cited for addition polymers is extended here to provide a measure of conditions under which depolymerization for recycling is favored.

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Parameter Estimation and Kinetic Monte Carlo Simulation of Styrene and n-Butyl Acrylate Copolymerization through ATRP

Cited by 13 publications

References 81 publications

Active Learning as a Tool for Optimizing “Plug‐n‐Play” Electrochemical Atom Transfer Radical Polymerization

Active Learning as a Tool for Optimizing “Plug‐n‐Play” Electrochemical Atom Transfer Radical Polymerization

Precision of Architecture-Controlled Bottlebrush Polymer Synthesis: A Monte Carlo Analysis

Kinetic Monte Carlo Tool for Kinetic Modeling of Linear Step‐Growth Polymerization: Insight into Recycling of Polyurethanes

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