Brownian Dynamics Simulation of the Capture of Primary Radicals in Dispersions of Colloidal Polymer Particles

Hernández, Hugo; Tauer, Klaus

doi:10.1021/ie070115c

Cited by 31 publications

(35 citation statements)

References 40 publications

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“…[9] The rates of radical capture obtained from the Brownian Dynamics simulations of dilute dispersions (volume fractions below 0.1%) in the absence of interaction potentials and in the absence of energy barriers for radical capture, were in very good agreement with the values predicted using the analytical solution derived by Smoluchowski [10] (Equation 1). On the other hand, a significant effect of volume fraction on radical capture rates was observed in systems above 0.1% volume fraction, where most polymer dispersions with any practical interest are found.…”

Section: Introductionsupporting

confidence: 76%

Brownian Dynamics Simulation Studies on Radical Capture in Emulsion Polymerization

Hernández¹,

Tauer²

2007

Macromolecular Symposia

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Summary: A computer simulation method based on the solution of the equations of Brownian motion is used to study the process of radical capture in emulsion polymerization. The effect of the size of the radical was studied, showing that as the radical grows its mobility is reduced (its diffusion coefficient decreases), and this leads to lower collision rates. The distance between the radicals and the surface of the particles at the moment of radical generation was found to be a very important factor in radical capture, with an increase of several orders of magnitude in the collision rate as the radical is generated closer to the particle surface. The effect of process temperature and interfacial barriers to radical capture on the collision rate and on the collision efficiency, defined as the ratio of successful radical captures to the total number of radical-particle collisions, is also analyzed. In the presence of an energy barrier, multiple collisions are observed, having an important effect on capture kinetics. The results obtained evidence the complexity involved in emulsion polymerization and demonstrates the capability of Brownian Dynamics simulation as a powerful tool for the study and understanding of such complex systems.

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Section: Introductionsupporting

confidence: 76%

Brownian Dynamics Simulation Studies on Radical Capture in Emulsion Polymerization

Hernández¹,

Tauer²

2007

Macromolecular Symposia

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“…In this case, when the diffusion coefficient in the core is small compared to the diffusion coefficient in the shell, the fitted parameters correspond to the values obtained using Equation (6), and therefore, the simple desorption rate coefficient can be estimated using the volume fraction averaged diffusion coefficient presented in Equation (5)…”

Section: Generation Of Radicals In Core and Shellmentioning

confidence: 67%

“…where j is a random number obtained from a Gaussian distribution with mean zero and variance 1, D p the diffusion coefficient of the radical inside the particle, and dt is the variable time-step which is constantly updated to reduce computation time, according to Equation (3): [6] dt…”

Section: Methodsmentioning

confidence: 99%

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Radical Desorption Kinetics in Emulsion Polymerization, 2 – Brownian Dynamics Simulation of Radical Desorption in Non‐Homogeneous Particles

Hernández¹,

Tauer²

2010

Macro Theory & Simulations

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One of the most important events in free‐radical emulsion polymerization is desorption of radicals from the polymer particles to the aqueous phase. Desorption takes place by diffusion of radicals inside the particle toward the surface and transfer to the aqueous phase. The rate of desorption can be determined theoretically for homogeneous spherical particles. For more complex cases, analytical solutions become difficult or impossible to obtain and a numerical approach is better suited for estimating desorption rate coefficients. In this paper, Brownian dynamics simulation is used for the estimation of desorption rate coefficients in emulsion polymerization systems of increased complexity, in particular for non‐homogeneous polymer particles.magnified image

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“…[28] These numerical experiments allow effective simulation of a variety of experimental conditions regarding the size and the concentration of the particles. Note, models relying on the Smoluchowski equation are insufficient as it is valid for a single particle at infinite dilution.…”

Section: Absorption Of Matter By Latex Particlesmentioning

confidence: 99%

Adaption of the Mechanism of Emulsion Polymerization to New Experimental Results

Tauer¹,

Hernández²,

Kozempel³

et al. 2007

Macromolecular Symposia

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Summary: New experimental investigations of the 'classical' batch ab-initio emulsion polymerization of styrene reveal the important role of monomer droplets for the whole process. Monomer droplets with a size between a few and some hundreds of nanometers, which are formed by spontaneous emulsification as soon as styrene and water are brought into contact, have a strong influence on the particle nucleation, the particle morphology, and the swelling of the particles. Experimental results confirm that micelles of low molecular weight surfactants are not a major locus of particle nucleation. Brownian dynamics simulations show that the capture of matter by the particles (monomer or radicals) strongly depends on the polymer volume fraction and the size of the captured species (primary free radicals, oligomers, single monomer molecules, or clusters).

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Brownian Dynamics Simulation of the Capture of Primary Radicals in Dispersions of Colloidal Polymer Particles

Cited by 31 publications

References 40 publications

Brownian Dynamics Simulation Studies on Radical Capture in Emulsion Polymerization

Brownian Dynamics Simulation Studies on Radical Capture in Emulsion Polymerization

Radical Desorption Kinetics in Emulsion Polymerization, 2 – Brownian Dynamics Simulation of Radical Desorption in Non‐Homogeneous Particles

Adaption of the Mechanism of Emulsion Polymerization to New Experimental Results

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