Didier Juhue scite author profile

The organization of liquid crystalline fluorinated acrylate polymers has been generally described so far in the literature in terms of phase segregation between hydrogenated and fluorinated moieties within the polymer and preferential orientation induced by the backbone. However, little is known on the effects of the chemical composition on the properties of such fluorine-containing polymers. Our study was then focused on the role played by the spacer group located in the side chain between the backbone and the fluorinated segment and, in particular, on the properties of poly [2-[[[[2-(perfluoroalkyl)ethyl]sulfonyl]methyl]amino]ethyl]acrylates (pASn). Surface and bulk organization of fluorinated side chains of those polymers were investigated by surface tension, X-ray scattering, and differential scanning calorimetry measurements. Results were compared with those obtained with poly[(perfluoroalkyl)ethyl] acrylates (pAFn) of the same perfluoroalkyl chain lengths. A strong correlation between bulk organization and surface properties of our polymers could be established. Surprisingly, in the perfluorohexyl series, pAS6 with a N-methylsulfonamide spacer group was found to be organized in a crystalline lamellar structure whereas pAF6 was found to be amorphous. This indicates that the introduction of a N-methylsulfonamide spacer group in the side-chain allows the system to crystallize with a shorter -C6F13 fluorinated segment, whereas in the presence of methylene groups, an organization is only present with a -C8F17 segment (pAF8). This was mainly attributed to the strong dipole-dipole interaction between N-methylsulfonamide groups that tends to align the fluorinated segments in a lamellar structure that eventually crystallizes as long as the section of the N-alkylsulfonamide group does not induce steric hindrance.

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Freeze-fracture studies of latex films formed in the absence and presence of surfactant

Wang¹,

Kats²,

Juhue³

et al. 1992

Langmuir

112

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Annealing effects on the surface structure of latex films studied by atomic force microscopy

Goh¹,

Juhue²,

Leung³

et al. 1993

Langmuir

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Surfactant exudation in the presence of a coalescing aid in latex films studied by atomic force microscopy¹

Juhue

Wang

Láng

et al. 1995

J Polym Sci B Polym Phys

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We report atomic force microscopy images of surfactant (SDS) exudation in PBMA latex films, in the presence and the absence of a coalescing aid (Texanol™, TPM). The exudates appear as hilly islets, and at times as mountains, at the film surface. Their size and number increase upon annealing above the glass‐transition temperature of the latex polymer. TPM was found to be a strong promoter of surfactant exudation at the air‐polymer interface. In the absence of TPM, annealing the films for several hours at 70°C led to very little migration of surfactant to the surface at most sites in the film. When the films with structures of SDS on their surface were immersed in water, these structures disappeared. Pores, ranging in size from tens to hundreds of nm in diameter, were clearly visible in the surface of the films. These films dry from the edges of the film inward, with a propagation front concentrating the water‐soluble species into a turbid, moist region in the center. At this site, the rate at which the surfactant comes to the surface is enormously enhanced over that at other sites in the film. This is likely due to the high concentration of surfactant in this region, transported there by the drying process. © 1995 John Wiley & Sons, Inc.

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Didier Juhue

Structure and Surface Properties of Liquid Crystalline Fluoroalkyl Polyacrylates: Role of the Spacer

Freeze-fracture studies of latex films formed in the absence and presence of surfactant

Annealing effects on the surface structure of latex films studied by atomic force microscopy

Surfactant exudation in the presence of a coalescing aid in latex films studied by atomic force microscopy¹

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Didier Juhue

Structure and Surface Properties of Liquid Crystalline Fluoroalkyl Polyacrylates: Role of the Spacer

Freeze-fracture studies of latex films formed in the absence and presence of surfactant

Annealing effects on the surface structure of latex films studied by atomic force microscopy

Surfactant exudation in the presence of a coalescing aid in latex films studied by atomic force microscopy1

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Surfactant exudation in the presence of a coalescing aid in latex films studied by atomic force microscopy¹