Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
As a kind of mass transfer process as well as the basis of separating and purifying mixtures, interfacial adsorption has been widely applied to fields like chemical industry, medical industry and purification engineering in recent years. Influencing factors of interfacial adsorption, in addition to the traditional temperature, intensity of pressure, amount of substance and concentration, also include external fields, such as magnetic field, electric field and electromagnetic field, etc. Starting from the point of thermodynamics and taking the Gibbs adsorption as the model, the combination of energy axiom and the first law of thermodynamics was applied to boundary phase, and thus the theoretical expression for the volume of interface absorption under electric field as well as the mathematical relationship between surface tension and electric field intensity was obtained. In addition, according to the obtained theoretical expression, the volume of interface absorption of ethanol solution under different electric field intensities and concentrations was calculated. Moreover, the mechanism of interfacial adsorption was described from the perspective of thermodynamics and the influence of electric field on interfacial adsorption was explained reasonably, aiming to further discuss the influence of thermodynamic mechanism of interfacial adsorption on purifying air-conditioning engineering under intensification of electric field.
Czasopismo
Rocznik
Tom
Strony
105--119
Opis fizyczny
Bibliogr. 19 poz., rys., wz.
Twórcy
autor
- First Affiliated Hospital of Wenzhou Medical College, Wenzhou, Zhejiang, 325000, China
Bibliografia
- [1] Xu H., Perumal S. X., Du N. et al.: Interfacial adsorption of antifreeze proteins: a neutron reflection study. Biophysical J. 94(2008), 1, 4405–4413.
- [2] Dan A., Wüstneck R., Krägel J. et al.: Interfacial adsorption and rheological behavior of ß-casein at the water/hexane interface at different pH. Food Hydrocolloid. 34(2014),193–201.
- [3] Kobyłecki R.: Carbonization of biomass – an efficient tool to decrease the emission of CO2. Microsc. Res. Techniq. 34(2013), 3, 185–195.
- [4] Saraf S., Neal C. J., Das S. et al.: Understanding the adsorption interface of polyelectrolyte coating on redox active nanoparticles using soft particle electrokinetics and its biological activity. Acs Appl. Mater. Interfaces, 6(2014), 8, 5472–5482.
- [5] Liping W., Riemsdijk W.H.V., Tijisse H.: Humic nanoparticles at the oxidewater interface: interactions with phosphate ion adsorption. Environ. Sci. Technol. 42(2008), 23, 8747–52.
- [6] Onorato R.M., Otten D.E., Saykally R.J.: Adsorption of thiocyanate ions to the dodecanol/water interface characterized by UV second harmonic generation. In: Proc. Nat. Aca. Sci. USA PNAS 106(2009), 36, 15176–15180.
- [7] Li H., Li R., Zhu H.L. et al.: Influence of electrostatic field from soil particle surfaces on ion adsorption-diffusion. Soil Sci. Soc. Am. J. 74(2010), 4, 1129–1138.
- [8] Eftekharibafrooei A., Borguet E.: Effect of electric fields on the ultrafast vibrational relaxation of water at a charged solid–liquid interface as probed by vibrational sum frequency generation. J. Phys. Chem. Lett. 2(2011), 12, 1353–1358.
- [9] Engelhardt K., Rumpel A., Walter J. et al.: Protein adsorption at the electrified air-water interface: Implications on foam stability. Langmuir 28(2012), 20, 7780–7.
- [10] Osamu S., Hiromichi N., Yoshikiyo M.: New adsorption model – theory, phenomena and new concept. J. Oleo Sci. 64(2015), 1, 1–8.
- [11] Perrier L, Pijaudier-Cabot G, Grégoire D.: Poromechanics of adsorption-induced swelling in microporous materials: a new poromechanical model taking into account strain effects on adsorption. Continuum Mech. Therm. 27(2014), 1–2, 195–209.
- [12] Altzibar J.M., Tamayo Ria I., Castro V.D. et al.: Extension of the asymptotically-correct approximation to Fowler-Guggenheim adsorption. Clin. Exp. Allergy 45(2014), 6, 1099–1108.
- [13] Schoot P.V.D.: Remarks on the interfacial tension in colloidal systems. Russ. Geol.d Geophys. 56(2015), 3, 446–465.
- [14] Brown P. S., Bhushan B.: Determination of the interfacial tension between oil–steam and oil–air at elevated temperatures. Apl Mater. 30(2016), 1, 15568–15573.
- [15] Hodge I.M.: Application of the thermorheologically complex nonlinear Adam-Gibbs model for the glass transition to molecular motion in hydrated proteins. Biophys. J. 91(2006), 3, 993–5.
- [16] Terpiłowski J., Piotrowska-Woroniak J., Romanowska J.: A study of thermal diffusivity of carbon-epoxy and glass-epoxy composites using the modified pulse method. Arch. Thermodyn. 35(2014), 3, 117–128.
- [17] Radke C.J.: Gibbs adsorption equation for planar fluid–fluid interfaces: Invariant formalism. Adv Colloid Interfac. 222(2015), 600–614.
- [18] Zhang J, Ding T, Zhang Z. et al.: Enhanced adsorption of trivalent arsenic from water by functionalized diatom silica shells. Plos One 10(2015), 4.
- [19] Liu F., Tang C.H.: Improvement of emulsification and interfacial adsorption by electrostatic screening. Food Hydrocolloid. 60(2016), 620–630.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-a2bc1cda-8ac3-43d1-a2c8-7d588b89b11f