Modeling free radical polymerization using dissipative particle dynamics

Understanding the details of free radical polymerization (FRP) in multi-component mixtures and solutions is of great importance for the synthesis of polymeric functional materials. Using the framework of dissipative particle dynamics (DPD), we develop a new computational approach to model FRP that c...

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Bibliographic Details
Published in:Polymer (Guilford) 2015-08, Vol.72, p.217-225
Main Authors: Yong, Xin, Kuksenok, Olga, Balazs, Anna C.
Format: Article
Language:English
Subjects:
Crosslinking
Dissipation
Dissipative particle dynamics
Dynamics
Fiber reinforced plastics
Fluid flow
Free radical polymerization
Polymer-clay nanocomposite gels
Polymerization
Reaction kinetics
Termination (polymerization)
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Summary:Understanding the details of free radical polymerization (FRP) in multi-component mixtures and solutions is of great importance for the synthesis of polymeric functional materials. Using the framework of dissipative particle dynamics (DPD), we develop a new computational approach to model FRP that couples the reaction kinetics for the polymerization processes to the dynamics of the complex fluid. We specifically consider two mechanisms of chain termination: disproportionation and combination. We analyze the effects of initiation, propagation, and termination on the polymerization kinetics in three-dimensional bulk polymerization by varying the corresponding reaction probabilities. Our model not only allows us to capture the interplay between hydrodynamics and reaction kinetics, but also provides an effective means to model polymerization in the presence of solid inclusions. We demonstrate the latter feature by simulating the formation of polymer-clay nanocomposite gels by FRP in solution in the absence of organic cross-linking agents, where the exfoliated clay particles serve as multi-functional cross-linkers for the polymer network. We observe that increasing the volume fraction of clay particles can lead to an increase in the number of inter-particle cross-linking chains, which could improve the mechanical properties of the material. Our findings provide insight into the polymerization kinetics of the FRP, as well as potential guidelines for tailoring experimental conditions to achieve the desired polymerization products. [Display omitted] •We model free radical polymerization using dissipative particle dynamics.•We examine the polymerization kinetics in bulk polymerization.•We demonstrate the formation of polymer-clay nanocomposite gels.•Increasing the clay loading can improve the mechanical properties of the material.
ISSN:0032-3861
1873-2291
DOI:10.1016/j.polymer.2015.01.052