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Adsorption of hexane and cyclohexane vapours at the water drop surface

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The dependence of the dynamic surface tension of water at the interface with saturated hexane and cyclohexane vapours was measured by the drop profile analysis method. The surface tension for the adsorption layers of cyclohexane at different temperatures was compared with the results reported earlier for the adsorption of hexane and other alkanes from the vapour phase on water drops. It is shown that cyclohexane is adsorbed significantly slower than the adsorption of hexane occurs, and is characterised by a much larger induction time. The error in the drop radius measurements at 40 ºC attains 45 m. The experimental rheologic characteristics of the adsorbed layers are studied and the results are compared with the model developed to describe an adsorption process governed by a kinetic mechanism.
Rocznik
Strony
54--62
Opis fizyczny
Bibliogr. 30 poz., rys., tab.
Twórcy
autor
  • MPI Colloids and Interfaces, Potsdam, Germany
  • Institute of Colloid Chemistry and Chemistry of Water, Kyiv (Kiev), Ukraine
  • Institute of Biocolloid Chemistry, Kyiv (Kiev), Ukraine
  • Institute of Colloid Chemistry and Chemistry of Water, Kyiv (Kiev), Ukraine
  • SINTERFACE Technologies, Berlin, Germany
Bibliografia
  • ASHBAUGH H.S., PETHICA B.A., 2003. Alkane adsorption at the water-vapor interface. Langmuir, 19, 7638−7645.
  • AVEYARD R., BINKS B.P., FLETCHER P.D.I., MACNAB J.R., 1996. The effect of temperature on the adsorption of dodecane onto nonionic and ionic surfactant monolayers at the air-water surface. Ber. Bunsen-Ges. Phys. Chem., 100, 224–231.
  • BINKS B.P., CRICHTON D., FLETCHER P.D.I., MACNAB J.R., LI Z.X., THOMAS R.K., PENFOLD J., 1999. Adsorption of oil into surfactant monolayers and structure of mixed surfactant+oil films. Colloids Surf. A, 146, 299-313.
  • FAINERMAN V.B., AKSENENKO E.V., KOVALCHUK V.I., JAVADI A., MILLER R., 2011. Study of the co-adsorption of hexane from the gas phase at the surface of aqueous С10ЕО8 drops. Soft Matter, 7, 7860-7865.
  • FAINERMAN V.B., AKSENENKO E.V., KOVALCHUK V.I., MILLER R., 2016a. Surface tension of water and C10EO8 solutions at the interface to hexane saturated air. Colloids Surf. A, 505, 118-123.
  • FAINERMAN V.B., AKSENENKO E.V., LYLYK S.V., TARASEVICH Yu.I., MILLER R., 2016b. Adsorption of surfactants and proteins at the interface between their aqueous solution drop and air saturated by hexane vapour. Colloids Surfaces A, 521, 211-220.
  • FAINERMAN V.B., AKSENENKO E.V., MILLER R., 2017. Influence of alkane and perfluorocarbons vapors on adsorbed surface layers and spread insoluble monolayers of surfactants, proteins and lipids. Adv. Colloid Interface Sci., 244, 100-112.
  • FAINERMAN V.B., LYLYK S.V., AKSENENKO E.V., MAKIEVSKI A.V., PETKOV J.T., YORKE J., MILLER R., 2009a. Adsorption layer characteristics of Triton surfactants. 1. Surface tension isotherms. Colloids Surf. A, 334, 1-7.
  • FAINERMAN V.B., LYLYK S.V., AKSENENKO E.V., MAKIEVSKI A.V., RAVERA F., PETKOV J.T., YORKE J., MILLER R., 2009b. Adsorption layer characteristics of Triton surfactants. 3. Dilational visco-elasticity. Colloids Surf. A, 334, 16-21.
  • GERBER F., KRAFFT M.P., VANDAMME T.F., GOLDMANN M., FONTAINE P., 2005. Preventing crystallization of phospholipids in monolayers: a new approach to lung surfactant therapy. Angew. Chem. Int. Ed., 44, 2749-2752.
  • GERBER F., KRAFFT M.P., VANDAMME T.F., GOLDMANN M., FONTAINE P., 2006. Fluidization of a dipalmitoyl phosphatidylcholine monolayer by fluorocarbon gases: Potential use in lung surfactant therapy. Biophys. J., 90, 3184-3192.
  • GUS’KOV V.Yu., GAJNULLINA Yu.Yu., KUDASHEVA F.H., 2014. Thermodynamic characteristics of adsorption of organic molecules on the surface of brominated polystyrene corbent. Sorption and Chromatographic Processes, 14, 270-274.
  • JAVADI A., MORADI N., FAINERMAN V.B., MÖHWALD H., MILLER R., 2011. Alkane vapor and surfactants co-adsorption on aqueous solution interfaces. Colloids Surf. A, 391, 19-24.
  • JAVADI A., MORADI N., MÖHWALD H., MILLER R., 2010. Adsorption of alkanes from the vapor phase on water drops measured by drop profile analysis tensiometry. Soft Matter, 6, 4710-4714.
  • KRAFFT M.P., FAINERMAN V.B., MILLER R., 2015. Modeling of the effect of fluorocarbon gases on the properties of phospholipid monolayers and the adsorption dynamics of their aqueous solutions or dispersions. Colloid Polymer Science, 293, 3091–3097.
  • KRAFFT M.P., RIESS J.G., 2007. Perfluorocarbons, life sciences and biomedical uses. J. Polymer Sci. Polymer Chem., 45, 1185-1198.
  • KWON O.S., JING H., SHIN K., WANG X., SATIJA S.K., 2007. Formation of n-alkane layers at the vapor/water interface. Langmuir, 23, 12249-12253.
  • LOU A.J., PETHICA B.A., 1997. Adsorption of hexane at the water/vapor interface. Langmuir, 13, 4933−4934.
  • MILLER R., AKSENENKO E.V., KOVALCHUK V.I., FAINERMAN V.B., 2017a. Adsorption of C14EO8 at the interface between its aqueous solution drop and air saturated by different alkanes vapor. Phys. Chem. Chem. Phys., 19, 2193-2200.
  • MILLER R., AKSENENKO E.V., KOVALCHUK V.I., TRUKHIN D.V., TARASEVICH Yu.I., FAINERMAN V.B., 2017b. Mixed protein/hexane adsorption layers formed at the surface of protein solution drops surrounded by hexane vapor. Advanced Materials Interfaces, 4, 1600031 (1-12).
  • MUCIC N., MORADI N., JAVADI A., AKSENENKO E.V., FAINERMAN V.B., MILLER R., 2015a. Mixed adsorption layers at the aqueous CnTAB solution / hexane vapor interface. Colloids Surf. A, 442, 50-55.
  • MUCIC N., MORADI N., JAVADI A., AKSENENKO E.V., FAINERMAN V.B., MILLER R., 2015b. Effect of partial vapor pressure on the co-adsorption of surfactants and hexane at the water/hexane vapor interface. Colloids Surf. A, 480, 79–84.
  • MYS V.D., FAINERMAN V.B., MAKIEVSKI A.V., KRAFFT M.P., MILLER R., 2015. Dynamic surface tension of С10ЕО8 at the aqueous solution/hexane vapor interface as measured by bubble pressure tensiometry. Colloids Surf. A, 483, 137–141.
  • NGUYEN P.N., TRINH DAHN T.T., WATON G., VANDAMME T.F., KRAFFT M.P., 2011. A nonpolar, nonamphiphilic molecule can accelerate adsorption of phospholipids and lower their surface tension at the air/water interface. Chem. Phys. Chem. 12, 2646-2652.
  • PETHICA B.A., 1996. Second virial coefficients for n-alkanes adsorbed at the vapor/water interface. Langmuir, 12, 5851−5855.
  • PETHICA B.A., GLASSER M.L., CONG E.H., 2003. Intermolecular forces between the n-alkanes methane to butane adsorbed at the water/vapor interface. Langmuir, 19, 6820−6825.
  • PETHICA B.A., GLASSER M.L., 2005. Lateral intermolecular forces in the physisorbed state: Surface field polarization of benzene and n-hexane at the water/ and Mercury/vapor interfaces. Langmuir, 21, 944−949.
  • SCHLOSSMANN M.L., 2002. Liquid-liquid interfaces: studied by X-ray and neutron scattering. Curr. Opin. Colloid Interface Sci., 7, 235-243.
  • TARASEVICH Yu.I., BONDARENKO S.V., ZHUKOVA A.I., 2009. Study of the energetic inhomogeneity of surface of modified layer silicates with rigid structural cell. Ukrainian Chemical Journal, 75, 72-77.
  • ZHOLOB S.A., MAKIEVSKI A.V., MILLER R., FAINERMAN V.B., 2011. Advances in calculation methods for the determination of surface tensions in drop profile analysis tensiometry. In: Bubble and Drop Interfaces, Progress in Colloid and Interface Science, Vol. 2, (ed. R. Miller and L. Liggieri), Brill Publ., Leiden, 2011, pp. 49–74.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-df72450e-02b4-42a0-8a20-62ac77585cf3
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