A Computational Study of the Polymerization‐Induced Phase Separation Phenomenon in Polymer Solutions under a Temperature Gradient

Lee, Kam-Wa D.; Chan, Philip K.; Feng, Xinbin

doi:10.1002/mats.200350003

Cited by 38 publications

(37 citation statements)

References 30 publications

(36 reference statements)

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“…2(a 0 ), 2(b 0 ), and 2(c 0 ) ] with otherwise identical parameters by setting D T 0 in Eq. (7). All other parameters of the model were kept constant and the same initial conditions were used [ Fig.…”

Section: (C)] and Moves Away From The Central Spot Like A Spherical Wmentioning

confidence: 99%

“…Yamamura et al [4] observed the formation of stripe patterns in demixing fluids caused by thermocapillary flow and Okinaka et al [5] describe directional phase separation of a polymer blend driven by a temperature gradient. Lee et al [6,7] performed a computational study on the spinodal decomposition process within a temperature gradient. Spatially periodic patterns formed after driving a binary polymer mixture periodically above and below the instability [8].…”

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Thermal Patterning of a Critical Polymer Blend

et al. 2005

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Utilizing the Soret effect, we have employed a moderately focused laser beam (30 microm, 20 mW) to write spatial composition patterns into layers of the critical polymer blend poly(dimethyl siloxane)/poly(ethyl-methyl siloxane) (PDMS/PEMS, M(w)=16.4/22.8 kg/mol) both in the one- and in the two-phase region a few degrees above and below the critical temperature T(c)=37.7 degrees C. Because of the critical divergence of the Soret coefficient, moderate temperature gradients are sufficient to induce composition modulations of large amplitude. In the two-phase regime the spinodal demixing pattern can be locally manipulated in a controlled way. 2D simulations based on a modified Cahn-Hilliard equation are able to reproduce the essential spatial and temporal features observed in the experiments.

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Section: (C)] and Moves Away From The Central Spot Like A Spherical Wmentioning

confidence: 99%

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confidence: 99%

Thermal Patterning of a Critical Polymer Blend

et al. 2005

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“…For instance, the permeability, throughput, and cleanability improve significantly for a polymer membrane with anisotropic pore size 7–10. Structural morphology can be influenced by imposing an external fluctuation, such as an electric field,11, 12 concentration gradient,13, 14 shear flow,15 or temperature gradient 16–18. For instance, Lee et al16–18 simulated a phase separation phenomenon via spinodal decomposition under a spatial temperature gradient (off‐critical quench) for both thermal‐induced and polymerization‐induced phase separation processes.…”

Section: Introductionmentioning

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Effect of Concentration Gradient on the Morphology Development in Polymer Solutions Undergoing Thermally Induced Phase Separation

Jiang

Chan

2007

Macro Theory & Simulations

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Anisotropic porous polymeric materials fabricated from the phase separation method via spinodal decomposition are used in various practical engineering applications. We studied the formation of anisotropic porous polymeric materials numerically, by imposing an initial linear concentration gradient across a model polymer solution. The initial concentration gradient is placed at three different regions of the polymer sample for comparison purposes. All the simulation results are in good agreement with published experimental observations, which are reported from the applications of porous polymeric membranes. The structure development shows that an anisotropic porous morphology forms when an initial linear concentration gradient is applied to the model polymer solution.magnified image

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“…Isothermal static and dynamical properties of polymer blends or solutions have been all well established; [27,28] however, there have been few experimental [29][30][31][32] or numerical studies [21,22] reported in the literature on the phase-separating polymer solutions and/or polymer blends under the influence of an externally applied…”

Section: Introductionmentioning

confidence: 99%

The Ludwig‐Soret Effect on the Thermally Induced Phase Separation Process in Polymer Solutions: A Computational Study

Kukadiya

Chan

Mehrvar

2009

Macro Theory & Simulations

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The Ludwig‐Soret effect was investigated in the thermally induced phase separation process via SD in polymer solutions under an externally imposed spatial linear temperature gradient using mathematical modeling and computer simulation. The mathematical model incorporated non‐linear Cahn‐Hilliard theory for SD, Flory‐Huggins theory for thermodynamics, and the Ludwig‐Soret effect for thermal diffusion. 2D simulation results revealed that the Ludwig‐Soret effect had negligible impact on the phase separation mechanism in binary polymer solutions under a non‐uniform temperature field, as reflected by the time evolution of the dimensionless structure factor and the transition time from the early to the intermediate stages of SD.magnified image

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A Computational Study of the Polymerization‐Induced Phase Separation Phenomenon in Polymer Solutions under a Temperature Gradient

Cited by 38 publications

References 30 publications

Thermal Patterning of a Critical Polymer Blend

Thermal Patterning of a Critical Polymer Blend

Effect of Concentration Gradient on the Morphology Development in Polymer Solutions Undergoing Thermally Induced Phase Separation

The Ludwig‐Soret Effect on the Thermally Induced Phase Separation Process in Polymer Solutions: A Computational Study

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