2018
DOI: 10.1002/adts.201800028
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Computational Design of Photocured Polymers Using Stochastic Reaction–Diffusion Simulation

Abstract: Photopolymerization is widely used for creating materials for biomedical applications, lithography, and fast 3D fabrication. The resin composition and curing protocol during polymerization define a high-dimensional parameter space that dictates the reaction kinetics, network structures, and physical properties of polymerized materials. But a quantitative map from the input parameter space to the transient and final properties does not exist. Here, a computational method is presented to simulate network growth … Show more

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Cited by 4 publications
(4 citation statements)
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“…As a complement to experimental characterization, modeling approaches can provide insights into the structure/property relationships of these complex resins. For example, there is an established body of work based on mathematical treatments of the polymer network growth and structure for chain-growth-based resins, such as population balance modeling and master equation approaches. , Such approaches have the advantage of being relatively unconstrained by limitations of system size (i.e., the number of chains, etc., under consideration) but correspondingly provide outputs at a relatively low level of structural resolution. In contrast, molecular simulations offer an alternative approach and can provide these atomic scale insights into the molecular-level structure of the 3D VER polymer network that can ultimately be correlated to the physicochemical properties of these resins.…”
Section: Introductionmentioning
confidence: 99%
“…As a complement to experimental characterization, modeling approaches can provide insights into the structure/property relationships of these complex resins. For example, there is an established body of work based on mathematical treatments of the polymer network growth and structure for chain-growth-based resins, such as population balance modeling and master equation approaches. , Such approaches have the advantage of being relatively unconstrained by limitations of system size (i.e., the number of chains, etc., under consideration) but correspondingly provide outputs at a relatively low level of structural resolution. In contrast, molecular simulations offer an alternative approach and can provide these atomic scale insights into the molecular-level structure of the 3D VER polymer network that can ultimately be correlated to the physicochemical properties of these resins.…”
Section: Introductionmentioning
confidence: 99%
“…Molecular simulations of many reaction-driven macroscopic phenomena are already on the way; see, for example, the studies on crystallization [4,27], self-assembly [28], aggregation [29], separation [30], and polymerization [7,9,31], and the concept of ordinary differential equations that learn from molecular simulations may facilitate the discovery of new macroscopic laws and improving existing kinetic models for these phenomena. As a proof of concept, we applied the method to diacrylate polymerization to reveal an intricate phenomenological dependance of the kinetic parameters on temperature and time in this system and postulated that these dependencies are induced by the complex evolution of the underlaying network.…”
Section: Discussionmentioning
confidence: 99%
“…Furthermore, the addition of thermomechanical modeling to the chemical kinetics permits the characterization of thermal expansion and chemical shrinkage of the cured polymer 30 . A further enhancement of the model quality is to consider the inherent stochasticity of the photopolymerization approach 31 . Herein, we utilized linear correlations between the exposure of the material and the resulting refractive index.…”
Section: Modeling Frameworkmentioning
confidence: 99%
“…30 A further enhancement of the model quality is to consider the inherent stochasticity of the photopolymerization approach. 31 Herein, we utilized linear correlations between the exposure of the material and the resulting refractive index. The final exposure film matrix was recorded as an image that which in turn was linked with the change in refractive index.…”
Section: Write Processmentioning
confidence: 99%