Microemulsion polymerization: Phase behavior driven mechanistic changes

Oliver Lade; Carlos C. Co; Patricia Cotts; Reinhard Strey; Eric W. Kaler

doi:10.1007/s00396-004-1238-5

Microemulsion polymerization: Phase behavior driven mechanistic changes

Oliver Lade, Carlos C. Co, Patricia Cotts, Reinhard Strey, Eric W. Kaler

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Abstract

We have examined the phase behavior of anionic microemulsions of the general type water/NaCl-hexyl methacrylate (C₆ MA)-bis(2-ethylhexyl)sulfosuccinate (AOT)/sodium dodecyl sulfate (SDS) with respect to temperature and composition. Monomer partitioning measurements and kinetic experiments show good agreement with the Morgan model (de Vries et al. in Macromolecules 34:3233, 2001) for droplet-type microemulsions that do not phase separate as monomer is consumed. In contrast, balanced microemulsions, which efficiently solubilize large amounts of monomer, exhibit dramatic effects on the polymerization kinetics as the phase behavior changes. Our findings suggest that the appearance of a liquid crystalline mesophase in the binary water-surfactant system of the respective microemulsion causes a phase separation during polymerization and, thus, a severe deviation from previous mechanistic models.

Original language	English (US)
Pages (from-to)	905-916
Number of pages	12
Journal	Colloid and Polymer Science
Volume	283
Issue number	8
DOIs	https://doi.org/10.1007/s00396-004-1238-5
State	Published - May 2005

Keywords

Alkyl methacrylate
Emulsification-failure boundary
Ionic surfactant
Kinetics
Mechanism
Microemulsion polymerization
Phase behavior
Phase inversion temperature

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title = "Microemulsion polymerization: Phase behavior driven mechanistic changes",

abstract = "We have examined the phase behavior of anionic microemulsions of the general type water/NaCl-hexyl methacrylate (C6 MA)-bis(2-ethylhexyl)sulfosuccinate (AOT)/sodium dodecyl sulfate (SDS) with respect to temperature and composition. Monomer partitioning measurements and kinetic experiments show good agreement with the Morgan model (de Vries et al. in Macromolecules 34:3233, 2001) for droplet-type microemulsions that do not phase separate as monomer is consumed. In contrast, balanced microemulsions, which efficiently solubilize large amounts of monomer, exhibit dramatic effects on the polymerization kinetics as the phase behavior changes. Our findings suggest that the appearance of a liquid crystalline mesophase in the binary water-surfactant system of the respective microemulsion causes a phase separation during polymerization and, thus, a severe deviation from previous mechanistic models.",

keywords = "Alkyl methacrylate, Emulsification-failure boundary, Ionic surfactant, Kinetics, Mechanism, Microemulsion polymerization, Phase behavior, Phase inversion temperature",

author = "Oliver Lade and Co, {Carlos C.} and Patricia Cotts and Reinhard Strey and Kaler, {Eric W.}",

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T2 - Phase behavior driven mechanistic changes

AU - Lade, Oliver

AU - Co, Carlos C.

AU - Cotts, Patricia

AU - Strey, Reinhard

AU - Kaler, Eric W.

PY - 2005/5

Y1 - 2005/5

N2 - We have examined the phase behavior of anionic microemulsions of the general type water/NaCl-hexyl methacrylate (C6 MA)-bis(2-ethylhexyl)sulfosuccinate (AOT)/sodium dodecyl sulfate (SDS) with respect to temperature and composition. Monomer partitioning measurements and kinetic experiments show good agreement with the Morgan model (de Vries et al. in Macromolecules 34:3233, 2001) for droplet-type microemulsions that do not phase separate as monomer is consumed. In contrast, balanced microemulsions, which efficiently solubilize large amounts of monomer, exhibit dramatic effects on the polymerization kinetics as the phase behavior changes. Our findings suggest that the appearance of a liquid crystalline mesophase in the binary water-surfactant system of the respective microemulsion causes a phase separation during polymerization and, thus, a severe deviation from previous mechanistic models.

AB - We have examined the phase behavior of anionic microemulsions of the general type water/NaCl-hexyl methacrylate (C6 MA)-bis(2-ethylhexyl)sulfosuccinate (AOT)/sodium dodecyl sulfate (SDS) with respect to temperature and composition. Monomer partitioning measurements and kinetic experiments show good agreement with the Morgan model (de Vries et al. in Macromolecules 34:3233, 2001) for droplet-type microemulsions that do not phase separate as monomer is consumed. In contrast, balanced microemulsions, which efficiently solubilize large amounts of monomer, exhibit dramatic effects on the polymerization kinetics as the phase behavior changes. Our findings suggest that the appearance of a liquid crystalline mesophase in the binary water-surfactant system of the respective microemulsion causes a phase separation during polymerization and, thus, a severe deviation from previous mechanistic models.

KW - Alkyl methacrylate

KW - Emulsification-failure boundary

KW - Ionic surfactant

KW - Kinetics

KW - Mechanism

KW - Microemulsion polymerization

KW - Phase behavior

KW - Phase inversion temperature

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SP - 905

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JO - Colloid and Polymer Science

JF - Colloid and Polymer Science

IS - 8

ER -

Microemulsion polymerization: Phase behavior driven mechanistic changes

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