2009
DOI: 10.1016/j.colsurfa.2009.06.037
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Rheology of colloidal gas aphrons (microfoams) made from different surfactants

Abstract: This paper extends our previous study on microfoam rheology made from non-ionic (Tween 20) surfactants to ionic surfactants. Anionic (sodium dodecyl sulfate) and cationic (cetyl trimethylammonium bromide) surfactants were used to generate microfoams by stirring an aqueous surfactant solution at high speed in a baffled beaker. Pipe flow experiments were performed in cylindrical stainless steel pipe 1.5 mm in diameter under adiabatic and fully developed laminar flow conditions. The porosity φ, bubble size distri… Show more

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Cited by 21 publications
(17 citation statements)
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“…For these, the wall shear stress consists of a yield stress and a viscous component, while it can be considered that only the second one is observed in foamy fluids. It is commonly admitted in the literature on wet foams that the viscous component scales with Ca 2/3 for mobile interfaces but with Ca 1/2 for immobile interfaces that correspond to protein-covered bubble interfaces (Zhao et al, 2009;Politova et al, 2012). The good agreement between foamy fluids and wet foams seems intuitive, as phenomena are similar, especially close to the very wet limit, although the assumptions leading to s $ Ca 1/2 in wet foams are not valid for foamy fluids.…”
Section: Rheology Of Foamy Fluids Under Continuous Shear Flowmentioning
confidence: 99%
“…For these, the wall shear stress consists of a yield stress and a viscous component, while it can be considered that only the second one is observed in foamy fluids. It is commonly admitted in the literature on wet foams that the viscous component scales with Ca 2/3 for mobile interfaces but with Ca 1/2 for immobile interfaces that correspond to protein-covered bubble interfaces (Zhao et al, 2009;Politova et al, 2012). The good agreement between foamy fluids and wet foams seems intuitive, as phenomena are similar, especially close to the very wet limit, although the assumptions leading to s $ Ca 1/2 in wet foams are not valid for foamy fluids.…”
Section: Rheology Of Foamy Fluids Under Continuous Shear Flowmentioning
confidence: 99%
“…[14] Rheological properties of CGAs have also been investigated by several researchers. [15][16][17] The stability of CGAs is a critical property for the above-mentioned applications. [18] The high stability of CGA dispersion shows its ability to resist changes in bubble size and liquid content.…”
Section: Introductionmentioning
confidence: 99%
“…About 100-300 bubbles were counted for each sample. Zhao et al [45] measured 130 to 240 individual bubbles using image analysis software and a microscope. Spinelli et al [30] used a similar microscope and image analysis software combination to work on the size distribution.…”
Section: Introductionmentioning
confidence: 99%