Jason Shin scite author profile

We report the use of UV light to control the dynamic surface tensions of mixed surfactant systems containing sodium dodecyl sulfate, SDS, and 4,4‘-bis(trimethylammoniumhexyloxy)azobenzene bromide, BTHA. The light influences the dynamic surface tension of these solutions by driving the isomerization of the azobenzene moiety from cis to trans. By combining use of the du Nouy ring, maximum bubble pressure, and Wilhelmy plate methods to measure dynamic and equilibrium surface tensions, the dynamic surface tension of an illuminated aqueous solution of these surfactants is demonstrated to be up to 25 mN/m lower than the dynamic surface tension of a solution not previously exposed to UV light. In contrast, the equilibrium surface tensions of these solutions change by less than 2 mN/m upon illumination. Measurements of quasi-elastic and static light scattering from these mixed surfactant solutions support our hypothesis that illumination influences the dynamic surface tension through its effect on the state of aggregation of the surfactant in bulk solution and thus the rate of mass transport of surfactant to the surface of the solution. A decrease in the number density of aggregates in solution upon illumination is observed. The decrease in dynamic surface tension that follows illumination is used to trigger the release of droplets of aqueous solution from a capillary at specified times. Patterned illumination is used to select the release of droplets from an array of droplets.

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Self‐Propagating High‐Temperature Synthesis of Aluminum Nitride under Lower Nitrogen Pressures

Shin

Ahn

Shin

et al. 2000

Journal of the American Ceramic Society

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The synthesis of aluminum nitride (AlN) via self-propagating high-temperature synthesis (SHS) was attempted, using aluminum powder that was mixed with AlN powder as a diluent. The AlN content in the reactant was varied over a range of 30%-70%, and the nitrogen pressure was varied over a range of 0.1-1.0 MPa. The SHS reaction that was performed using a reactant that contained 50% AlN diluent, under a nitrogen-gas pressure of 0.8 MPa, yielded the highest conversion ratio of aluminum powder to AlN powder. A mechanism for the reaction of aluminum with nitrogen gas during the SHS process was discussed, based on observations of the microstructures of the reaction zone and products.

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Three Principles for Active Control of Interfacial Properties of Surfactant Solutions

Jong¹,

Abbott²,

Aydoğan³

et al. 2001

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Dynamic Interfacial Properties of Mixed Surfactant Systems Containing Light-Sensitive Surfactants

Shin¹,

Abbott²

2004

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Jason Shin

Using Light to Control Dynamic Surface Tensions of Aqueous Solutions of Water Soluble Surfactants

Self‐Propagating High‐Temperature Synthesis of Aluminum Nitride under Lower Nitrogen Pressures

Three Principles for Active Control of Interfacial Properties of Surfactant Solutions

Dynamic Interfacial Properties of Mixed Surfactant Systems Containing Light-Sensitive Surfactants

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