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http://dx.doi.org/10.9713/kcer.2018.56.5.767

Extended Maxwell-Wagner Polarization Model with Onsager Theory for the Electrorheological Phenomena  

Kim, Young Dae (School of Chemical Engineering, Chonnam National University)
Publication Information
Korean Chemical Engineering Research / v.56, no.5, 2018 , pp. 767-772 More about this Journal
Abstract
Among various mechanisms for ER phenomena, the electrostatic polarization and conduction models were known as the most promising theoretical models. However, many inherited defects have limited their uses for the development of effective ER fluids. To resolve these problems, extended Maxwell-Wagner polarization model with Onsager theory was developed. It was observed that the extended model resolved the problems, suggesting that the extended model can be used for the development of effect ER fluids.
Keywords
Electrorheology; Electrorheological fluids; Maxwell-Wagner polarization; Onsager theory; Suspension;
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1 Klingenberg, D. J. and Zukoski, C. F., "Studies on the Stedy-shear Behavior of Electrorheological Suspensions," Langmuir, 6, 15-24(1990).   DOI
2 Davis, L. C. and Ginder, J. M., "Elevtrostatic Forces in Electro-rheological Fluids," Progress in Electrorheology, ed. by K.O. Havelka and F.E. Filisko, New York, Plenum, 107-111(1995).
3 Foulc, J. N., Atten, P. and Felici, N., "Macroscopic Model of Interaction between Particles in an Electrotheological Fluid," J. Electrostatics, 33, 103-112(1994).   DOI
4 Parthasarathy, M. and Klingenberg, D. J., "Electrorheology: Mechanisms and Models," Mater. Sci. Eng., R17, 57-103(1996).
5 Von Hippel A. R., Dielectric Materials and Applications, Cambridge and Wiley, New York(1954).
6 Kim, Y. D. and Park, D. H., "The Electrorheological Responses of Suspensions of Polypyrrole-coated Polyethylene Particles," Colloid Polym. Sci., 280, 828-834(2002).   DOI
7 Onsagar, L., "Deviation from Ohm's Law in Weak Electrolytes," J. Chem. Phys., 2, 599-615(1934).   DOI
8 Klingenberg, D. J., Dierking, D. and Zukoski, C. F., "Stress Transfer Mechanism in Electrorheological Suspensions," J. Chem. Soc. Faraday Trans., 87, 425-430(1991).   DOI
9 Kim, D. H. and Kim, Y. D., "Electrorheological Properties of Polypyrrole and its Composite ER Fluids," J. Ind. Eng. Chem., 13(6), 879-894(2007).
10 Filisko, F. E. and Razdilowski, L. H., "An intrinsic Mechanism for the Activity of Aumino-silicate Based Electrorheological Materials," J. Rheo., 34, 539-552(1990).   DOI
11 Otsubo, Y., Sakine, M. and Katayama, S., "Effect of Adsorbed Water on the Electrorheology of Silica Suspensions," J. Coll. Interface Sci., 150, 324-330(1992).   DOI
12 Kim, Y. D. and Klingenberg, D. J., "Two roles of Nonionic Surfactants on the Electrorheological Response," J. Coll. Interface Sci., 168, 568-578(1996).
13 Shin, K., Kim, D., Cho, J-C., Lim, H-S., Kim, J. W. and Suh, K- D., "Monodisperse Conducting Colloidal Dipoles with Symmetric Dimer Structure for Enhancing Electrorheology Properties," J. Coll. Interface Sci., 374, 18-24(2012).   DOI
14 Hao, T., "Electrorheological Suspensions," Adv. Colloid Interface Sci., 97, 1-35(2002).   DOI
15 Winslow, W. M., "Induced Fibration of Suspensions," J. Appl. Phys., 20, 1137-1140(1949).   DOI
16 Deinega, Y. F. and Vinogradov, G. V., "Electric fields in Rheology of Disperse System," Rheol Acta., 23, 636-651(1984).   DOI
17 Shulman, Z. P., Gorodkin, R. G. and Korobko, E. V., "The Electrorheological Effects and Its Possible Uses," J. Non-Newt. Fluid Mech., 8, 29-41(1981).   DOI
18 Stangroom, J. E., "Basic Considerations in Flowing Electrorheologcal Fluids," J. Stat. Phys., 64, 1059-1072(1991).   DOI
19 Noh, J., Yoon, C. M. and Jang, J., "Enhanced Electrorheological Activity of Polyaniline Coated Mesoporous Silica with High Aspect Ratio," J. Coll. Interface Sci., 470, 237-244(2016).   DOI
20 Lengalova, A., Pavlinek, B., Saha, P., Stejskal, J. and Quadrat, O., "Electrorheology of Polyaniline-coated Inorganic Particles in Silicone oil," J. Coll. Interface Sci., 258, 174-178(2003).   DOI
21 Kim, Y. D., "A Surfactant Bridge Model for the Nonlinear Electrorheological Effects of Surfactant Activated ER Suspensions," J. Coll. Interface Sci., 236, 225-232(2001).   DOI
22 Klass, D. L. and Martinek, T.W., "Electro-viscous Fluids," J. Appl. Phys. 38, 67-75(1967).   DOI
23 Block, H. and Kelly, J. P., "Electro-heology," J. Phys. D: Appl. Phys., 21, 1661-1677(1988).   DOI
24 Liu, Y. D. and Choi, H. J., "Electrorheological Fluids: Smart Soft Matter and Characteristics," Soft Matter, 8, 11961-11978 (2012).   DOI