Modeling the Permittivity of Liquid Mixtures

References

• Baker, G. A. (Jr). And Gammel, Y. L. 1970. The Pade Approximant in Theoretical Physics, Academic Press, New York.
   Google Scholar
• Bengtsson, N. E. and Risman, P. O. 1971. Dielectric properties of foods at 30Hz as determined by a cavity perturbation technique. J. Microwave Power 6: 107–123.
   Google Scholar
• Dube, D. 1970. Study of Landau-Lifshitz-Looyenga’s formula for dielectric correlation between powder and bulk. J. Phys. D. : Appl. Phys., 3, 1648–1652.
   Google Scholar
• Dube, D., Yadav, R. and Prashad, R. 1971. A formula for correlating dielectric constants of powder and bulk. J. Phys. D. Appl. Phys., 9, 719–721.
   Google Scholar
• Engelder, S. D. and Buffler, R. C. 1991. Measuring dielectric properties of food products at microwave frequencies. Microwave World 12 (2): 6–14.
   Google Scholar
• Kraszewslci, A. 1977. Prediction of the dielectric properties of two phase mixtures. J. Microwave Power 12 (3): 215–222.
   Google Scholar
• Kraszewski, A. 1979. Model of the dielectric properties of grain at microwave frequencies. Institute of Electrical Engineers Conference Publication 177: 174–177.
   Google Scholar
• Kraszewski, A., Kulinski, S. andMatuszewski, M. 1976. Dielectric properties and a model of biphase water suspension at 9.4 GHz. J. Appl. Phys. 47 (4): 1275–1277.
   Google Scholar
• Kraszewski, A. and Nelson, S. O. 1989. Composite Model of the Complex Permittivity of Cereal Grain. J. Agric. Engng. Res. 43: 211–219.
   Google Scholar
• Kress-Rogers, E. and Kent, M. 1987. Microwave measurement of powder moisture and density. J. Food Engineering 6: 345–376.
   Google Scholar
• Landau, L. D. and Lifshitz, E. M. 1960. Electrodynamics of Continuous Media, Vol. 8, Course of Theoretical Physics. Transl. From Russian by Sykes, J. B., and Bell, J. S., Pergamon Press Inc., Oxford, England, pp. 45–47.
   Google Scholar
• Looyenga, H. 1965. Dielectric constants of hetrogeneous mixtures. Physica 31: 401–406.
   Google Scholar
• Mudgett, R. E. and Goldblith, D. I. C. 1977. Prediction of dielectric properties in solid foods of high moisture content at ultrahigh and microwave frequencies. J. Food Proc. and Perserv. 1: 119–151.
   Google Scholar
• Mudgett, R. E., Smith, A. C., Wang, D. I. C., and Goldblith, S. A. 1971. Prediction of the relative dielectric loss factor in aqueous solutions of nonfat dried milk through chemical simulation. J. Food Sci. 36(6): 915–918.
   Google Scholar
• Nelson. S. O. 1976. Microwave dielectric properties of insects and grain kernels. J. Microwave Power 11(4): 299–303.
   Google Scholar
• Nelson, S. O. 1983. Observations on the density dependence of dielectric properties of particulate materials. J. Microwave Power 18(2): 143–152.
   Google Scholar
• Nelson, S. O. 1985a. A mathematical model for estimating dielectric constants of hard red winter Transactions of the ASAE 28(1): 234–238.
   Google Scholar
• Nelson, S. O. 1985b. Mathematical models for dielectric constants of spring barley and oats. Transactions of the ASAE 29(2): 607–610.
   Google Scholar
• Nelson, S. O. 1986, Models for estimating the dielectric constant of winter barley. J. Microwave Power 2(3): 189–200.
   Google Scholar
• Nelson, S. O. 1987, Models for the dielectric constant of cereal grains and soybeans, J. Microwave Power 22(1): 35–39.
   Google Scholar
• Nelson, S. O. and You T.-S. 1990. Relationship between microwave permittivities of solid and pulverised plastics. J. Phys. D: Appl. Phys. 23: 346–353.
   Google Scholar
• Pade, H., 1892. These, Ann. Ecole Nor. 9, Suppl. 1.
   Google Scholar
• Ptitsyn, S. D., Sekanov, Y. P. and Batalin, M. Y. 1982. Modelling the dielectric properties of grain, Mekhanizatsiya I Elektrifikatsiya Sel’ skogo Khozyaistva. 12: 47–49.
   Google Scholar
• Roebuck, B. D., Goldblith, S. A. and Westphal. W. 1972. Dielectric properties of carbohydrate-water mixtures at microwave frequencies. J. Food Sci 37(2): 199–204.
   Google Scholar
• Roy, P. B., Roy, S. B. and Thakur, K. P. 1992. A critical study of the phenomenon of ion-solvent interaction and enthalpy of solution of ionic gaseous :iiciecules. Proc. Indian National Sci. Acad. 58A: 433441
   Google Scholar
• Sanderson, R. T. 1967 The role Ofrodinate Covalence in Non-molecular Solids (Edited by R. F. Gould) in Advances in Chemistry 62: 1K.
   Google Scholar
• Subedi, P. and Chatterjee, I. 1993. Dielectric mixture model for asphalt-aggregate mixtures. J. Microwave Power and Electroma7n Energy, 23(2): 68–72.
   Google Scholar
• Sun, E., Datta, A. and Lobo, S. 1995. Composition-based prediction of dielectric properties of foods, J. Microwave Power and Eiectromagn. Energy. 30(4): 205–212.
   Google Scholar
• Taylor, L. 1965. Dielectric properties of mixtures. I. E. E. E. Trans. Antennas Propag., AP-13,(6)
   Google Scholar
• Thakur, K. P. 1978. Equation state for solids under high pressures, with application to alkali halides. Applied Physics, 16: 201–8.
   Google Scholar
• Thakur, K. P. 1982. Compressibility coefficient and Moelwyn-Hughes parameters for solids under pressure. Phys. Earth Planet. Interoid. (UK), 27: 235–50
   Google Scholar
• Thakur, K. P. and Dwari, B. D. 1986. Behaviour of Sodium chloride crystal on its P-V-T surface. J. Phys. C: Solid State Physics, 19: 3069–81.
   Google Scholar
• Tinga, W., Voss, W. and Blossey, D. 1973. Generalised approach to multiphase dielectric mixture theory J. Appl. Phys., 44: 3897
   Google Scholar
• Tulasidas, T. N., Raghavan, G. S. V., van de Voort, F., and Girard, R. 1995. Dielectric properties of grapes and sugar solutions at 2.45 GHz. J. Microwave Power and Electromagn. Energy. 30 (2): 117–123.
   Google Scholar