Radical Lifetimes in Atom Transfer Radical Polymerization: A Monte Carlo and Deterministic Investigation

Keating, John J.; Plawsky, Joel L.

doi:10.1021/acs.macromol.0c01263

Cited by 10 publications

(17 citation statements)

References 53 publications

(117 reference statements)

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“…In PRE, one of the most studied processes is solution/bulk conventional or free radical polymerization (FRP). [ 38–45 ] The core FRP reactions are displayed in Figure a, focusing on homopolymerization utilizing I 2 as conventional radical initiator and M as monomer. At elevated temperature, I 2 dissociates to form an initiator radical I that reacts with one monomer molecule through so‐called chain initiation to obtain a macroradical of chain length 1 ( R 1 ).…”

Section: Introductionmentioning

confidence: 99%

“…[31,[34][35][36][37] In PRE, one of the most studied processes is solution/ bulk conventional or free radical polymerization (FRP). [38][39][40][41][42][43][44][45] The core FRP reactions are displayed in Figure 1a, focusing on homopolymerization utilizing I 2 as conventional radical Bulk and solution radical polymerization is important in daily live. A challenge is still to maximize polymerization rate and control over molecular characteristics such as the molar mass distribution.…”

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confidence: 99%

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Benchmarking Stochastic and Deterministic Kinetic Modeling of Bulk and Solution Radical Polymerization Processes by Including Six Types of Factors Two

Keer

Figueira

Marien

et al. 2020

Macro Theory & Simulations

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Bulk and solution radical polymerization is important in daily live. A challenge is still to maximize polymerization rate and control over molecular characteristics such as the molar mass distribution. The last decades have made clear that kinetic modeling is indispensable with originally most focus on deterministic implementations such as the method of moments (MoM) and only more recently promising results for event‐driven kinetic Monte Carlo (kMC) simulations that belong to stochastic methods. Computationally, a critical reaction is termination for which one has both distinguishable and nondistinguishable distributed species, which requires a delicate treatment of a stoichiometric factor 2. Proper benchmarking of MoM and kMC simulations demands thus a careful translation of this factor in the Monte Carlo (MC) reaction probabilities. However, limited attention has been paid in the kMC field to the detailed description of such translations. Here, a rigorous derivation is presented on the level of individual termination rates. Emphasis is on termination by recombination and disproportionation. It is highlighted that six types of factor 2 exist that all need to be incorporated with care, including an IUPAC‐based one. The consistency is demonstrated by a successful benchmark of essential modeling results for free radical polymerization of methyl methacrylate.

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

Benchmarking Stochastic and Deterministic Kinetic Modeling of Bulk and Solution Radical Polymerization Processes by Including Six Types of Factors Two

Keer

Figueira

Marien

et al. 2020

Macro Theory & Simulations

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“…This means that the apparent termination rate is based on larger radicals, resulting in a lower < k t,app > value and thus a slightly higher (strictly incorrect) monomer conversion. In contrast, at higher monomer conversions, the calculation method for < k t,app > becomes less relevant as the NMP becomes more and more controlled due to the well-established persistent radical effect, , greatly reducing the radical concentration and thus the relevance of termination reactions also as with increasing average chain length diffusional limitations are more pronounced. , …”

Section: Resultsmentioning

confidence: 99%

“…In contrast, at higher monomer conversions, the calculation method for <k t,app > becomes less relevant as the NMP becomes more and more controlled due to the well-established persistent radical effect, 107,108 greatly reducing the radical concentration and thus the relevance of termination reactions also as with increasing average chain length diffusional limitations are more pronounced. 50,109 The dormant polymer CLD is additionally shown in Figure 3(e) at three monomer conversions: 5, 30, and 60%. Since the radical concentrations are very low, we opted to plot the CLD for the dormant chains as active radicals are generated almost exclusively out of this population and radical MC profiles are not free from noise unless extremely large initial numbers of molecules are selected.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Roadmap for Monomer Conversion and Chain Length-Dependent Termination Reactivity Algorithms in Kinetic Monte Carlo Modeling of Bulk Radical Polymerization

Smit

Marien

Edeleva

et al. 2020

Ind. Eng. Chem. Res.

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Radical polymerization is prone to diffusional limitations on termination, leading to a rate acceleration by the gel-effect and molecular changes, with strong increases in average chain length in free radical polymerization (FRP) and improvement of the end-group functionality in reversible deactivation radical polymerization. What complicates the correct implementation of the termination rates in kinetic modeling studies is (i) the chain length and monomer conversion dependence of the individual (apparent) termination rate coefficients (k t,app,ij values; i,j: chain length) and (ii) the wide variations in macroradical chain length distribution (CLD) types and shapes along the polymerization and upon altering the reaction conditions, including variations in CLD modality and broadness. In this work, we compare four major kinetic Monte Carlo modeling algorithms to sample termination reaction events in bulk radical polymerization, using literature k t,app,ij values. We present a roadmap allowing one to select the most suited algorithm depending on the radical polymerization technique and reaction conditions, therefore opening the pathway to more correct representations of chain length and monomer conversion dependencies in radical polymerization. Case studies are related to bulk nitroxide-mediated polymerization, FRP, and pulsed laser polymerization, following an increasing complexity in the active macroradical CLD type and shape.

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“…The active (propagating) radical concentration is low enough to reduce the contribution of radical–radical termination, which can occur through radical coupling or disproportionation due to this shift. At the same time, quick initiation and deactivation with low stationary radical concentrations are essential for extending the life span of polymer chains, resulting in improved control over the final polymer [ 57 ]. Zhao et al, for example, presented the ATRP approach for the synthesis of dextran- g -poly (2-dimethylaminoethyl methacrylate- co -2-lactobionamidoethyl methacrylate (DDrLs)/PEI complexes [ 58 ], which is seen schematically in Fig.…”

Section: Glycopolymer Synthesis Methodologiesmentioning

confidence: 99%

Glycopolymer-Based Materials: Synthesis, Properties, and Biosensing Applications

et al. 2022

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Glycopolymer materials have emerged as a significant biopolymer class that has piqued the scientific community's attention due to their potential applications. Recently, they have been found to be a unique synthetic biomaterial; glycopolymer materials have also been used for various applications, including direct therapeutic methods, medical adhesives, drug/gene delivery systems, and biosensor applications. Therefore, for the next stage of biomaterial research, it is essential to understand current breakthroughs in glycopolymer-based materials research. This review discusses the most widely utilized synthetic methodologies for glycopolymer-based materials, their properties based on structure–function interactions, and the significance of these materials in biosensing applications, among other topics. When creating glycopolymer materials, contemporary polymerization methods allow precise control over molecular weight, molecular weight distribution, chemical activity, and polymer architecture. This review concludes with a discussion of the challenges and complexities of glycopolymer-based biosensors, in addition to their potential applications in the future. Graphical Abstract

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Radical Lifetimes in Atom Transfer Radical Polymerization: A Monte Carlo and Deterministic Investigation

Cited by 10 publications

References 53 publications

Benchmarking Stochastic and Deterministic Kinetic Modeling of Bulk and Solution Radical Polymerization Processes by Including Six Types of Factors Two

Benchmarking Stochastic and Deterministic Kinetic Modeling of Bulk and Solution Radical Polymerization Processes by Including Six Types of Factors Two

Roadmap for Monomer Conversion and Chain Length-Dependent Termination Reactivity Algorithms in Kinetic Monte Carlo Modeling of Bulk Radical Polymerization

Glycopolymer-Based Materials: Synthesis, Properties, and Biosensing Applications

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