Controlling colloid charge in nonpolar liquids with surfactants

Abstract: The formation of ions in nonpolar solvents (with relative permittivity ε r of approximately 2) is more difficult than in polar liquids; however, these charged species play an important role in many applications, such as electrophoretic displays. The low permittivities (ε r) of these solvents mean that charges have to be separated by large distances to be stable (approximately 28 nm or 40 times that in water). The inverse micelles formed by surfactants in these solvents provide an environment to stabilize ions … Show more

“…This paper does not demonstrate any significant effect of varying solvent-surfactant interactions for ionic surfactants in alkanes, but these materials are very interesting to study, given their applications as microemulsion stabilizers [8], as nanoreactors [9], and as charge control agents [10]. This provides a strong motivation to gain further understanding into their aggregation.…”

“…This surfactant does not have a solvophobic increment like the surfactants shown in Figure 1, but AOT is an interesting and well-studied model surfactant that is important in numerous applications as, for example, a microemulsion stabilizer [8], as a micellar nanoreactor [9], or as a charge control agent [10]. Understanding how this surfactant forms inverse micelles at low concentrations is important for efficient and controllable use in applications.…”

The effect of solvent and counterion variation on inverse micelle CMCs in hydrocarbon solvents

“…This paper does not demonstrate any significant effect of varying solvent-surfactant interactions for ionic surfactants in alkanes, but these materials are very interesting to study, given their applications as microemulsion stabilizers [8], as nanoreactors [9], and as charge control agents [10]. This provides a strong motivation to gain further understanding into their aggregation.…”

“…This surfactant does not have a solvophobic increment like the surfactants shown in Figure 1, but AOT is an interesting and well-studied model surfactant that is important in numerous applications as, for example, a microemulsion stabilizer [8], as a micellar nanoreactor [9], or as a charge control agent [10]. Understanding how this surfactant forms inverse micelles at low concentrations is important for efficient and controllable use in applications.…”

The effect of solvent and counterion variation on inverse micelle CMCs in hydrocarbon solvents

“…Dispersions of colloids in nonpolar solvents are prevalent in soft matter nanoscience [1][2][3][4][5][6][7][8][9][10][11][12]. The significance of such dispersions can be appreciated by considering the many various industrial sectors that make use of them, which include petrochemicals [13], lubricants [7,14,15], reprography [4,5], inkjet printing [5], magnetic recording media [4], rheological fluids [16,17], and electronic displays [18][19][20][21].…”

The internal structure of poly(methyl methacrylate) latexes in nonpolar solvents

“…1,2 The formation of charged species is important in many nonaqueous systems, including petroleum safety and the electrophoretic displays used in electronic paper devices. 3,4 A common system used to produce charged species in nonpolar solvents is by preparing dispersions of poly(methyl methacrylate) (PMMA) latexes with poly(12-hydroxystearic acid) (PHSA) brushes as steric stabilizers and the anionic surfactant, sodium dioctylsulfosuccinate (Aerosol OT or AOT), added as CCA.…”

Interaction between Surfactants and Colloidal Latexes in Nonpolar Solvents Studied Using Contrast-Variation Small-Angle Neutron Scattering