Abstract
Rigorous design of industrial microwave processing systems requires in-depth knowledge of the dielectric properties of the materials to be processed. These values are not easy to measure, particularly when a material is multi-layered containing multiple phases, when one phase has a much higher loss than the other and the application is based on selective heating. This paper demonstrates the ability of the Clausius–Mossotti (CM) model to predict the dielectric constant of multi-layered materials. Furthermore, mixing rules and graphical extrapolation techniques were used to further evidence our conclusions and to estimate the loss factor. The material used for this study was vermiculite, a layered alumina-silicate mineral containing up to 10 % of an interlayer hydrated phase. It was measured at different bulk densities at two distinct microwave frequencies, namely 934 and 2143 MHz. The CM model, based on the ionic polarisability of the bulk material, gives only a prediction of the dielectric constant for experimental data with a deviation of <5 % at microwave frequencies. The complex refractive index model, Landau, Lifshitz and Looyenga, Goldschmidt, Böttcher and Bruggeman–Hanai model equations are then shown to give a strong estimation of both dielectric constant and loss factor of the solid material compared to that of the measured powder with a deviation of <1 %. Results obtained from this work provide a basis for the design of further electromagnetic processing systems for multi-layered materials consisting of both high loss and low loss components.
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Gallego Carrera D, Mack A (2010) Sustainability assessment of energy technologies via social indicators: results of a survey among European energy experts. Energy Policy 38(2):1030–1039
Robinson J, Kingman S, Irvine D, Licence P, Smith A, Dimitrakis G, Obermayer D, Kappe CO (2010) Understanding microwave heating effects in single mode type cavities—theory and experiment. Phys Chem Chem Phys 12(18):4750–4758
Tuhkala M, Juuti J, Jantunen H (2013) Method to characterize dielectric properties of powdery substances. J Appl Phys 114(1):014108
Nelson SO (1992) Estimation of permittivities of solids from measurements on pulverised or granular materials. In: Kong JA (ed) Progress in electromagnetics research (Chap. 6). Elsevier Science and Technology, New York, pp 231–271
Metaxas AC, Meredith RJ (1983) Industrial microwave heating, 1st edn. The Instritute of Engineering and Technology, London
Wang M, Pan N (2008) Predictions of effective physical properties of complex multiphase materials. Mater Sci Eng R Rep 63(1):1–30
Olaosebikan F, Christopher D, Georgios D, Samuel K (2012) Continuous energy efficient exfoliation of vermiculite through microwave heating. Int J Miner Process 114–117:69–79. doi:10.1016/j.minpro.2012.10.003
Kingman S, Vorster W, Rowson N (2000) The influence of mineralogy on microwave assisted grinding. Miner Eng 13(3):313–327
Jones D, Lelyveld T, Mavrofidis S, Kingman S, Miles N (2002) Microwave heating applications in environmental engineering—a review. Resour Conserv Recycl 34(2):75–90
Vorster W, Rowson N, Kingman S (2001) The effect of microwave radiation upon the processing of Neves Corvo copper ore. Int J Miner Process 63(1):29–44
Ballantyne G, Holtham P (2010) Application of dielectrophoresis for the separation of minerals. Miner Eng 23(4):350–358
Foster MD (1960) Interpretation of the composition of trioctahedral micas. US Government Printing Office, Washington, DC
Newman A, Brown G (1966) Chemical changes during the alteration of micas. Clay Miner 6(29):310
El Mouzdahir Y, Elmchaouri A, Mahboub R, Gil A, Korili SA (2009) Synthesis of nano-layered vermiculite of low density by thermal treatment. Powder Technol 189(1):2–5
Bain D, Smith B (1994) Chemical analysis. Clay mineralogy: spectroscopic and chemical determinative methods. Springer, Berlin, pp 300–332
Hippel ARV (1954) Dielectrics and waves, 3rd edn. Wiley, Massachusetts
Sucher M, Fox J, Wind M (1963) Handbook of microwave measurements, vol 2. Polytechnic Press of the Polytechnic Institute of Brooklyn, New York
Venkatesh MS, Raghavan GVS (2005) An overview of dielectric properties measuring techniques. Can Biosyst Eng 47(7):15–30
Baker-Jarvis J, Geyer RG, Grosvenor JH Jr, Janezic MD, Jones CA, Riddle B, Weil CM, Krupka J (1998) Dielectric characterization of low-loss materials a comparison of techniques. IEEE Trans Dielectr Electr Insul 5(4):571–577
Anderson JC (1964) Dielectrics. Chapman and Hall London, London
Smith AD, Lester EH, Thurecht KJ, Kingman SW, El Harfi J, Dimitrakis G, Robinson JP, Irvine DJ (2010) Temperature dependence of the dielectric properties of 2, 2′-Azobis (2-methyl-butyronitrile)(AMBN). Ind Eng Chem Res 49(6):3011–3014
Adams F, De Jong M, Hutcheon R (1992) Sample shape correction factors for cavity perturbation measurements. J Microw Power Electromagn Energy 27(3):131–135
Clarke B, Gregory A, Cannell D, Patrick M, Wylie S, Youngs I, Hill G (2003) A guide to the characterisation of dielectric materials at Rf and microwave frequencies. Institute of Measurement and Control/National Physical Laboratory, New Delhi
Hilhorst M, Dirksen C, Kampers F, Feddes R (2000) New dielectric mixture equation for porous materials based on depolarization factors. Soil Sci Soc Am J 64(5):1581–1587
Doyle WT (1978) The Clausius-Mossotti problem for cubic arrays of spheres. J Appl Phys 49(2):795–797. doi:10.1063/1.324659
Shannon RD (1993) Dielectric polarizabilities of ions in oxides and fluorides. J Appl Phys 73(1):348–366. doi:10.1063/1.353856
Robinson DA (2004) Calculation of the dielectric properties of temperate and tropical soil minerals from ion polarizabilities using the clausius mosotti equation. Soil Sci Soc Am J 68:1780–1785
Nelson SO (1994) Measurement of microwave dielectric properties of particulate materials. J Food Eng 21(3):365–384
Sheen J (2009) Measurements of microwave dielectric properties by an amended cavity perturbation technique. Measurement 42(1):57–61
Sihvola A (2000) Electromagnetic mixing formulas and applications. IEE Electromagnetic Wave, vol 1, 1st edn. The institution of Electrical Engineers, London
Sihvola A (2000) Mixing rules with complex dielectric coefficients. Subsurf Sens Technol Appl 1(4):393–415
Reynolds J, Hough J (1957) Formulae for dielectric constant of mixtures. Proc Phys Soc London Sect B 70(8):769
Knoll MD (1996) A petrophysical basis for ground penetrating radar and very early time electromagnetics: electrical properties of sand-clay mixtures. PhD Thesis, University of British Columbia. https://circle.ubc.ca/handle/2429/6136
Chang CS (1988) Measuring density and porosity of grains kernels using a gas pycnometer. Am Soc Cereals Chem 65(1):13–15
Kent M (1977) Complex permittivity of fish meal: a general discussion of temperature, density and moisture dependence. J Microw Power 12:341–345
Klein A (1981) Microwave determination of moisture in coal-comparison of attenuation and phase measurement. J Microw Power Electromagn Energy 16(3 & 4):289–304
Nelson SO, You TS (1989) Relationships between microwave permittivities of solids and pulverised plastics. J Phys D 23:346–353
Metaxas A, Meredith R (1988) Industrial microwave heating. Peter Peregrinus Ltd., London
Kent M (1977) Complex permitivity of fish-meal-general discussion of temperature, desnity and moisture dependance. J Microw Power Electromagn Energy 12(4):341–345
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Katrib, J., Folorunso, O., Dodds, C. et al. Improving the design of industrial microwave processing systems through prediction of the dielectric properties of complex multi-layered materials. J Mater Sci 50, 7591–7599 (2015). https://doi.org/10.1007/s10853-015-9319-z
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DOI: https://doi.org/10.1007/s10853-015-9319-z