REFERENCES

Adler, P. M., Porous Media: Geometry and Transports, Butterworth­Heinemann, Boston, Ch. 2, 1992.

Aitchinson, G.D., and C.C. Wood, Some interactions of compaction, permeability and post-construction deflocculation affecting probability of piping failure in small earthen dams, 6th Inti. Conf. on Soil Mechanics and Foundation Engr., Montreal, Canada, Vol. 2, 442-446, 1965.

Anderson, W.G., Wettability literature survey - Part I: Rock-Oil-Brine interactions and the effects of core handling on wettability, J. Pet. Technol., October, 1125-1144, 1986a.

Anderson, W.G., Wettability literature survey - Part 2: Wettability measurements,J. Pet. Technol., November, 1246-1262, 1986b.

Arulanadan K, P. Loganathan, and R.B. Krone, Pore and eroding fluid influences on surface erosion of soil, J. Geotech. Engin. Div., ASCE, 101 (1), 51--65, 1975.

Arulanandan K, E. Gillogley, and R. Tulley, Development of quantitative methods to predict critical shear and rate of erosion of natural undisturbed cohesive soils, Technical Report GL-80-5, USCOE Waterways, Exp. Stn., Vickshurg, Miss. 1980.

Arulanandan K, and B.B. Perry, Erosion in relation to filter design criteria in earth dams, J. Geotech. Engin. Div., ASCE, 109(5),682--698, 1983.

Bales, R.C., S.R. Hinkle, T.W. Kroeger, K Stocking, and C.P. Gerba, Bacteriophage adsorption during transport through porous media: Chemical perturbations and reversibility, Environ. Sci. Technol., 25, 2088-2095, 1991.

Barenblatt, G.I., V.M. Entov, and V.M. Ryzhik, Theory of Fluid Flows through Natural Rocks, Kluwer Academic Publishers, Boston, Chapter 4, 1990.

Barouch, E., T.H. Wright, and E. Matijevic, Kinetics of particle detachment 1. General considerations, J. Colloid Interface Sci., 118(2), 473-481, 1987.

Bear, J., and V. Bachmat, Introduction to Modelling of Transport in Porous Media, Kluwer Academic Publishers, Boston, Chapter 4, 1990.

155

156 REFERENCES

Bhuniya S.K., Flow of Suspension through Packed Beads: Studies on the Influences of the Particle Concentration, M. Tech. Thesis, lIT Bombay, 1996.

Biswas, T.D., and S.K. Mukherjee, Text Book of Soil Science, Tata McGraw Hill, New Delhi, Chapter 2, 1994a.

Biswas, T.D., and S.K. Mukherjee, Text Book of Soil Science, Tata McGraw Hill, New Delhi, Chapter 4, 1994b.

Borchardt, J.K., and D.L., Brown, Clay stabilizers improve injection rates, Oil Gas J., Sept., 150-156, 1984.

Bryant, S.L., D.W. Mellor, and c.A. Cade, Physically representative network models of transport in porous media, AIChE J., 39(3), 387-396, 1993.

Burganos, V.N., C.A. Paraskeva, and A.C. Payatakes, Three dimensional trajectory analysis and network simulation of deep bed filtration, J. Colloid Interface SeL, 148, 167-181, 1992.

Cerda, C.M., Mobilization of kaolinite fines in porous media, Colloids Surfaces, 27, 219-241, 1987.

Cerda, C.M., Mobilization of quartz fines in porous media, Clays Clay Minerals, 36,491--497,1988.

Chedda, P., D. Grasso, and C.J. van ass, Impact of ozone on stability of montmorillonite suspensions, J. Colloid Interface Sci., 153(1), 226-236, 1992.

Christenson, H.K., Non-DLVO forces between surfaces - solvation, hydration and capillary effects, J. Dispersion Sci. Techno!., 9(2) 171-206, 1988.

Cleaver, J.W., and B. Yates, Mechanism of detachment of colloidal particles from a flat substrate in a turbulent flow, J. Colloid Interface SeL, 44(3), 464--474, 1973.

Clementz, D.M., Clay stabilizattion of sandstones through adsorption of petroleum heavy ends, J. Pet. Technol., 21, 1061-1066, 1977.

Collins, R.E., Flow of Fluids through Porous Materials, Reinhold Publishing Corporation, New York, Chapter 1, 1960.

Collins,R.E., Flow of Fluids through Porous Materials, Reinhold Publishing Corporation, New York, Chapter 1, 1990.

Coppe1, c.P., H.Y. Jennings, and M.G. Reed, Field results from wells treated with hydroxy-aluminum, J. Pet. Technol., Sept., 1108-1112, 1973.

Corapciog1u, M.Y., and S. Jiang, Colloid-facilitated groundwater contaminant transport, Water Resour. Res., 29(7), 2215-2226, 1993.

Coulter, A.W., C.T., Copeland, and W.H. Harrisberger, A Laboratory study of clay stabilizers, Soc. Pet. Engin. J., Oct., 267-270, 1979.

REFERENCES 157

Craig, F.F., The Reservoir Engineering Aspects of Water-Flooding, Monograph Series, SPE, Richardson TX, 3, 1971.

Dahneke, B., Kinetic theory of escape of particles from surface, J. Colloid Interface Sci., 50(1), 89-107, 1975a.

Dahneke, B., Resuspension of particles, J. Colloid Interface Sci., 50(1), 194-196, 1975b.

Das, S.K., R.S. Schechter, and M.M. Sharma, The role of surface roughness and contact deformation on the hydrodynamic detachment of particles from surface, J. Colloid Interface Sci., 164,63-77, 1994.

Derjaguin B.V., V.M. Muller, and VP. Toporov, Effect of contact deformation on the adhesion of particle, J. Colloid Interface Sci., 53, 314-326,1975.

Dias, M.M., and A. C. Payatakes, Network models for two-phase flow itt porous media: Part 1. Immiscible micro-displacement of non-wetting fluids, J. Fluid Mech., 164,305-336,1986.

Donaldson, E.C., B.A. Baker, and H.B. Carrol, Particle transport in sandstones, SPE 6905, 52nd Annual Technical Conference and Exhibition of SPE, 1977.

Dullien, F.A.L., and G.K. Dhawan, Characterization of pore structure by a combination of quantitative photomicrography and mercury porosimetry, J. Colloid Interface Sci., 47(2),337-349, 1974.

Dullien, F.A.L., Porous Media, Fluid Transport and Pore Structure, Academic Press, New York, Chapter 3, 1979a.

Dullien, F.A.L., Porous Media, Fluid Transport and Pore Structure, Academic Press, New York, Chapter 2, 1979b.

Eichholz, G.G., B.G. Wahlig, G.F. Powell, and T.F. Craft, Subsurface migration of radioactive waste materials by particulate transport, Nuclear Technol., 58,511-520, 1982.

Flair, G.M., J.e. Geyer, and D.A. Okun, Water and Wastewater Engineering, Vol. 2, Water Purification and Wastewater Treatment and Disposal, John Wiley and Sons, New York, Chapter 27,1968.

Fair, M.C., and J.L. Anderson, Electrophoresis of non-uniformly charged ellipsoidal particles, J. Colloid Interface Sci., 127(2),388-400, 1989.

Fatt, I., The network model of porous media, Pet. Trans. AIME, 207,141-188, 1956.

Feke, D.L., N.D. Prabhu, J.A. Mann Jr., and J.A. Mann III, A formulation of the short range repulsion between spherical colloidal particles, J. Phys. Chem., 88, 5735-5739, 1984.

Fogler, H.S., Elements of Chemical Reaction Engineering, 2nd Ed., Prentice

158 REFERENCES

Hall, Englewood Cliffs, New Jersey, Chapter 12, 1992. Fowkes, F.M.,Role of acid-base interfacial bonding in adhesion, J. Adhesion

Sci. Technol., 1, 7-27, 1987. Gerba, C.P., C. Wallis, and J.L. Melnick, Fate of wastewater bacteria and

viruses in soil, J. Irrig. Drain. Div. ASCE, 101, 157-174, 1975. Goldenberg, L.c., M. Magaritz, and S. Mandel, Experimental investigation on

irreversible changes in hydraulic conductivity in seawater-fresh water in coastal aquifers, Water Resour. Res., 19(1), 77---!d5, 1983.

Goldman, S., K. Jackson and T.A. Brusztynsky, Erosion and Sediment Control Handbook, McGraw Hill, New York, Chapter 1, 1986.

Gray, D.H., and R. Rex, Fonnation damage in standstones caused by dispersive clays, Proc. 14th Nat!. Con! on Clays and Clay Minerals, Berkeley, 355-366, 1966.

Gray, D.H., Khilar, K. C., and Fogler, H.S., Piping and plugging as a result of clay dispersion I swelling in porous media, Interim Report Submitted to NSF Grant No. CEE-8313765, Washington, D.C., 1985.

Greenkorn, R.A., Flow Phenomena in Porous Media: Fundamentals and Applications in Petroleum, Water and Food Productions, Marcel Dekker Inc., New York, Chapter 3,1983.

Grim, R.E., Clay Mineralogy, McGraw Hill, New York, Chapter 6, 1968. Gruesbeck, C., and R.E. Collins, Entrainment and deposition of fine particles

in porous media, Soc. Pet. Engin. J., Dec., 847---!d56, 1982. Hardcastle, J.H., and J.K. Mitchel, Electrolyte concentration penneabi1ity

relationships in sodium-illite silt mixtures, Clays Clay Minerals, 22, 143-154, 1974.

Harvey, R.W., George, L.H., Smith, R.L., and LeBlanc, D.R., Transport of micro spheres and indigenous bacteria through a sandy aquifer: Results of natural- and forced tracer experiments, Environ. Sci. Technol., 23,51-56, 1989.

Harvey, R.W., and S.P. Garabedian, Use of colloid filtration theory in modeling movement of bacteria through a contaminated sandy aquifer, Environ. Sci. Technol., 25, 178-185, 1991.

Helffrich, F., Ion Exchange, McGraw Hill, New York, Chapter 4, 1962. Herrero, C., P. Pradanos, J.1. Calvo, F. Tejerina and A. Hernandez, Flux dec1in;;

in protein microfiltration: influence of operative parameters, J. Colloid Interface Sci., 187,344-351,1997.

Herzig J.P., D.M. Leclerc, and P. Legoff, Flow of suspension through porous media - Applications to deep bed filtration, Ind. Engin. Chem., 62(5), 8-35,

REFERENCES 159

1970. Hesterberg, D., and M.G. Reed, Volumetric treatment efficiencies of some

commercial stabilizers, SPE Production Engin., Feb., 57---62, 1991. Hewitt, C.H., Analytical techniques for recognizing water sensitive reservoir

rocks, J Pet. Technol., Trans AIME, 15(8), 813-817, 1963. Hiemenz, P.e., Principles of Colloid and Surface Chemistry, Second Edition,

Revised and Expanded, Marcel Dekker Inc, New York, Chapter-13, 1986. Himes, RE., E.F. Vinson, and D.E. Simon, Clay stabilization in low

permeability formations, SPE Production Engin., Aug., 252-258, 1991. Hjeldness E.I., and B. Y.K. Lavania, Cracking leakage and erosion of earth dam

materials, J Geotech. Engin. Div., ASCE, 106, 117-135,1980. Ho, N.F.H., and W.I. Higuchi, Preferential aggregation and coalescence in

heterodisperesed systems, J Pharm. Sci., 57, 436--443, 1968. Hoefner, M.L., and H.S. Fogler, Pore evolution and channel formation during

flow and reaction in porous media, AIChE J, 34(1), 45-54, 1988. Hogg, R., T.W. Healy, and D.W. Fuerstenau, Mutual coagulation of colloidal

dispersions, Trans. Faraday Soc., 62, 1633-1651, 1966. Hopkins, M.R., and K.M. Ng, Liquid-liquid relative permeability, network

models and experiments, Chem. Engin. Commun., 46, 253-279,1986. Houi, D. and R Lenormand, Particle accumulation at the surface of a filter,

Filtration Separation, 238-241, 1986. Hubbe, M.A., Theory of detachment of colloidal particles from flat surfaces

exposed to flow, Colloids Surfaces, 12, 151-178, 1984. Hunter, RJ., Zeta Potential in Colloid Science, Academic Press, New York,

Chapter 4, 1981. Hunter, R.J., Foundations of Colloid Science, Vol. 1, Oxford Univ. Press,

Chapter 7, 1989a. Hunter, R.J., Foundations of Colloid Science, Vol. 1, Oxford Univ. Press,

Chapter 4, 1989b. Imdakm, A.O., and M. Sahimi, Transport of large particles in flow through

porous media, Phys. Rev. A, 36(11), 5304-5309,1987. Imdakm, A.O., and M. Sahimi, Computer simulation of particle transport

processes in flow through porous media, Chem. Engin. Sci., 46(8), 1977-1993, 1991.

Ioannidis, M.A., and I. Chatzis, Network modeling of pore structure and transport properties of porous media, J Colloid Interface Sci., 48(5),951-972, 1993.

Israelachvili, J.N., Intermolecular and Surface Forces with Applications to

160 REFERENCES

Colloidal and Biological Systems, Academic Press, New York, Chapter 12, 1992a.

Israelachvili, J.N., Intermolecular and Surface Forces with Applications to Colloidal and Biological Systems, Academic Press, New York, Chapter 11, 1992b.

Jerauld, G.R., lC. Hatfield, L.E. Scriven, and H.T. Davis, Percolation and conduction on voronoi and triangular networks: A case study in topological disorder,.!. Phys. C. Solid State Physics, 17,1519-1529,1984.

Jones, Jr., F.O., Influence of chemical composition of water on clay blocking of permeability, J. Pet. Technol., April, 441--446,1964.

Kallay, N, and E. Matijevic, Particle adhesion and removal in model systems Part-IV: Kinetics of detachment of hematite particles from steel,'!' Colloid Interface Sci., 83(1),289-300, 1981.

Kallay, N., B. Biskup, M. Tomic, and E. Matijevic, Particle adhesion and removal in model systems Part- X: The effect of electrolytes on particle detachment,'!' Colloid Interface Sci., 114(2),357-362,1986.

Kaplan, D.l., P.M. Bertsch, D.C. Andriano, and W.P. Miller, Soil-borne mobile colloids as influenced by water flow and organic carbon, Environ. Sci. Technol., 27, 1193-1200, 1993.

Kar, G., S. Chandar, and T.S. Mika, The potential energy of interaction between dissimilar electrical double layers, J. Colloid Interface Sci., 44(2), 347-355, 1973.

Karickhoff, S.W., D.S. Brown, and T.A. Scott, Sorption of hydrophobic pollutants on natural sediments, Water Res., 13,241-248, 1979.

Khilar, K.C., The Water Sensitivity of Berea Sandstones, Ph.D. thesis, The University of Michigan, Ann Arbor, 1981.

Khilar K.C., and H.S. Fogler, Permeability reduction in water sensitivity of sandstones, in Surface Phenomena in Enhanced Oi/Recovery, Ed. D. Shah), Plenum, 721-739,1981.

Khilar, K.C., and H.S. Fogler, Water sensitivity of sandstones, Soc. Pet. Engin . .!., 23(1), 55--64, 1983.

Khilar K.C., H.S. Fogler, and J.S. Ahluwalia, Sandstone water sensitivity : Existence of a critical rate of salinity decrease for particle capture, Chem. Engin. Sci., 38, 789-800, 1983.

Khilar, K.C., Effect of streaming potential on permeability of sandstones, Ind. Engin. Chem. Fundam., 22, 264--266, 1983.

Khilar, K.C., and H.S. Fogler, The existence ofa critical salt concentration for particle release,.!. Colloid Interface Sci., 100(1), 214--224, 1984.

REFERENCES 161

Khilar K.C., H.S. Fogler, and D.H. Gray, A model for piping and plugging in earthen structures, J Geotech. Engin. Div. ASCE, 111(7),833-846, 1985.

Khilar, K.C., and H.S. Fogler, Colloidally induced fines migration in porous media, Rev. Chem. Engin., 4(1 & 2), 41 - 108, 1987.

Khilar K.C., and D.S.H. Sita Ram Sarma, Colloidally and hydrodynamically induced fines migration in porous media, Chapter-19, in Encyclopedia of Fluid Mechanics, Vol. 10, Surface and Ground Water Flow Phenomena, Ed. N.P. Cheremisinoff, 623-663,1990.

Khilar, K.C., R.N. Vaidya, and H.S. Fogler, Colloidally induced fines release in porous media, J Petro. Engin. Sci., 4, pp. 213-221,1990.

Kia, S.P., H.S. Fogler, and M.G. Reed, Effects of pH on colloidally induced fines migration, J Colloid Interface Sci., 118(1), 158-168, 1987a.

Kia, S.P., H.S. Fogler, M.G. Reed, and R.N. Vaidya, Effect of salt composition on clay release in Berea sandstone, SPE Production Engin., Nov., 277-283, 1987b.

Kirkpatrick, S., Percolation and conduction, Rev. Mod. Phys., 45(4),574-588, 1973.

Kolakowski, J.E., and E. Matijevic, Particle adhesion and removal in model systems, Part 1 - Monodispersed chromium hydroxide on glass, J Chem. Soc. Faraday Trans., I 75(1), 65-78,1979.

Kuo, R.J., and E. Matijevic, Particle adhesion and removal in model systems: Part 2 - Monodispersed chromium hydroxide on steel, J. Chem. Soc. Faraday Trans., I 75(8), 2014 - 2026, 1979.

Kuo, R.J., and E. Matijevic, Particle adhesion and removal in model systems: Part III - Monodispersed ferric oxide on steel, J. Colloid Interface Sci., 78(2), 407-421, 1980.

Lappan, R.E., and H.S. Fogler, Leuconostoc mesentroides growth kinetics with applications to bacterial proifle modification, Biotech. Bioengin., 430, 865-873, 1994.

Lappan, R.E., and H.S. Fogler, Reduction of porous media permeability from insitu leuconostoc mesentroides growth and dextran production, Biotech. Bioengin., 50, 6-15, 1996.

Lauzon, R.V., Chemical balance stops formation damage, Oil Gas J, Sept., 124-126, 1982.

Leichtberg, S., R. Pfeffer, and S. Weinbaum, Stokes flow past finite coaxial clusters of spheres in a circular cylinder, Int. J Multiphase Flow, 3, 147-169, 1976.

Lin, C.Y., and lC. Slattery, Three dimensional, randomized network model

162 REFERENCES

for two-phase flow through porous media, AIChE J., 28(2), 311-324,1982. Leone, J.A., and M.E. Scott, Characterization and control offormation damage

during water flooding of a high clay content reservoir, SPE Reservoir Engin., Nov., 1279-1285,1988.

Lever A., and R.A. Dowe, Water sensitivity and migration of fines in the Hopeman sandstone,J. Pet. Geology, 7(1), 97-108,1984.

Lin, C., and M.H. Cohen, Quantitative methods for microgeometric modeling, J. Appl. Phys., 53(6), 4152-4165,1982.

Lindqvist, R., J.S. Cho, and G.G. Enfield, Kinetic model for cell density dependent bacterial transport in porous media, Water Resour. Res., 30(12), 3291-3299, 1994.

Lymberopoulos, D.P. and A.e. Payatakes, Derivation of topological, geometrical, and correlational properties of porous media from pore-chart analysis of serial section data, J. Colloid Interface Sci., 150(1), 61-81, 1992.

Magaritz, M., A.J. Amiel, D. Ronen, and M.C. Wells, Distribution of metals in polluted aquifer: A comparison of aquifer suspended material to fine sediment of adjacent enviomment, J. Contaminant Hydrology, 5, 333-347, 1990.

Magee, B.R., L.W. Lion, and A.T. Lemley, Transport of dissolved organic macromolecules and their effect on the transport of phenanthrene in porous media, Environ. Sci. Technol., 25,323-331, 1991.

McCabe, W.L., J.e. Smith, and P. Harriott, Unit Operations of Chemical Engineering, 5th Edition, McGraw Hill, New York, Chapter 30, 1993.

McCarty, P.L., Environmental Biotechnology: Bioengineering Issues Related to Insitu Remediation of Contaminated Soils and Groundwater, Plenum, New York, 143-162,1987.

McCarthy, J.P', and J.M. Zachara, Subsurface transport of contaminants, Environ. Sci. Technol., 23(5), 496-502, 1989.

McDowel-Boyer L.M., J.R. Hunt, and N. Sitar, Particle transport through porous media, Water Resour. Res., 22(13), 1901-1921, 1986.

McLaughlin Sr., H. C., E.A. Elphingstone, R.E. Remington II, and S. Contes, Clay stabilzing agent can correct formation damage, World Oil, May, 58-60,1977.

Mohan K.K., Water Sensitivity of Porous Media Containing Swelling Clays, Ph.D. thesis, The University of Michigan, Chapter V, 1996a.

Mohan K.K., Water Sensitivity of Porous Media Containing Swelling Clays, Ph.D. thesis, The University of Michigan, Chapter III, 1996b.

REFERENCES 163

Mohan K.K., and H.S. Fogler, Colloidally induced smectitic fines migration: Existence of micro quakes, AIChE J., 43,565-576, 1997.

Mohanty, J. and B.W. Ninhan, Dispersion Forces, Academic Press, New York, Chapter 2, 1976.

Monaghan, P.H., R.E. Salatheil, and B.E. Morgan, Laboratory studies of formation damage in sands containing clays, J. Pet. Techno!. Trans, AIME, 11(2),209-215,1959.

Moore, J.E., How to combat swelling clays, Petrol. Engineer, 32, 78-101, 1960.

Morrision, A., Hazarads waste landfills: Can clay liners prevent migration of toxic leachate?, Civil Engin. ASCE, 60-63, July 1981.

Muecke, T.W., Formation fines and factors controlling their movement in porous media, J. Pet. Technol., Feb., 144-150, 1979.

Mungan, N., Permeability reduction through changes in pH and salanity, J. Pet. Techno!., Trans. AIME, 17, 1449-1453, 1965.

O'Connor, D.J. and J.P. Connolly, The effecct of cocncentration of adsorbing solids on the partition coefficient, Water Res., 14, 1517-1523,1980.

O'Neill, M.E., A Sphere in contact with a plane wall in a slow linear shear flow, Chern. Engin. Sci., 23, 1293-1297, 1968.

Pandya, v.B., S. Bhuniya and K.C. Khilar, Existence of a critical particle concentration in plugging ofa packed bed, AIChE J., 44, 978-981, 1998.

Parker, G.G., and E.A. Jenne, Structural failure of western US highways caused by piping, 46th Annual Meeting of Hwy. Res. Board, Washington, D.C., 1967.

Payatakes, A.C., H.Y. Park, and J. Petrie, A visual study of particle depositon and reentrainment during depth filtration of hydro sols with a polyelectrolyte, Chern. Engin. Sci., 36, 1319-1335, 1981.

Penrose, W.R, W.L. Polzer, E.H. Essington, D.M. Nelson, and K.A. Orlandini, Mobility of plutonium and americum through a shallow aquifer in a semiarid region, Environ. Sci. Technol., 24(2), 228-234, 1990.

Peters, F. W. and C.M. Stout, Clay stabilization during fracturing treatments with hydrolyzable zirconium salts, J. Pet. Technol., AIME, Feb., 187-194, 1977.

PuIs, RW., and RM. Powell, Transport of inorganic colloids through natural aquifer materials: Implications for contaminant transport, Environ. Sci. Technol., 26(3), 614--621,1992.

Quirk, J.P., and R.K. Schofield, The effect of electrolyte concentration on soil permeability, J. Soil Sci., 20(1), 163-178, 1966.

164 REFERENCES

Reed, M.G., Stabilization of fonnation clays with hydroxy-aluminum solutions, J Pet. Technol., July, 860-864, 1972.

Rege, S.D., and H.S. Fogler, Network model for straining dominated particle entrapment in porous media, Chem. Engin. Sci., 42(7), 1553-1564,1987.

Rege, S.D., and H.S. Fogler, A network model for deep bed filtration of solid particles and emulsion drops, AIChE J, 34(11), 1761-1772, 1988.

Rowel, D.L., D. Payne, and H. Ahmed, The effect of the concentration and movement of solutions on the swelling and disperson, J Soil. Sci., 20(1), 176-188, 1969.

Ruckenstein, E., and D.C. Prieve, Adsorption and desorption of particles and their choromatographic separation, AIChE J, 22(2), 276-283, 1976a.

Ruckenstein,E., and D.C. Prieve, On reversible adsorption of hydro sols and repeptization, AIChE J, 22(6), 1145-1147, 1976b.

Ryan, J.N., and P.M. Gschwend, Effects of ionic stength and flow rate on colloid release: Relating kinetics to intersurface potential energy, J Colloid Interface Sci., 164,21-34,1994.

Ryan, J.N., and M. Elimelech, Colloid mobilization and transport in groundwater, Colloids Surfaces, 107, 1-56, 1996.

Sahimi, M., H.T. Davis, and L.E. Scriven, Dispersion in disordered porous media, Chem. Engg. Commun., 23,329-341,1983.

Sahimi, M., and T.T. Tsotsis, A percolation model of catalyst deactivation by site coverage and pore blockage, J Catal., 96, 552-567, 1985.

Sahimi, M., Flow and Transport in Porous Media and Fractured Rocks: From Classical Methods to Modern Approaches, VCH, New York, Chapter 5, 1995a.

Sahimi, M., Flow and Transport in Porous Media and Fractured Rocks: From Classical Methods to Modern Approaches, VCH, New York, Chapter 6, 1995b.

Sanchez, R.L., A.I. Strutynsky, and M.A. Silver, Evaluation of erosion potential of embankment core materials using the laboratory biaxial erosion test procedure, Technical Report, GL-83-4, USCOE Waterways Exp. Stn., Vickshurg, Miss, 1983.

Schechter, R.A, Oil Well Stimulation, Prentice Hall, Englewood Cliffs, New Jersey, Chapter 1, 1992.

Scheidegger, A., The Physics of Flow through Porous Materials, University of Toronto Press, Toronto, Chapter 1, 1974.

Scholl, M.A., and R.W. Harvey, Laboratory investigations on the role of sediment surface and ground water chemistry in transport of bacteria

REFERENCES 165

through a contaminated sandy aquifer, Environ. Sci. Technol., 26, 141 ~ 1417,1992.

Schweich, D., and M. Sardin, Transient ion exchange and solubilization of limestone in an oil field sandstone : Experimental and theoretical wave front analysis, AIChE J., 31(11), 1882-1890, 1985.

Sharma, M.M., and T.F. Yen, Interfacial electrochemistry of oxide surfaces in oil-bearing sands and sandstones, J. Colloid Interface Sci., 98, 39-54, 1984.

Sharma, M.M., IF. Kuo, and T.F. Yen, Further investigation of the surface charge properties of oxide surfaces in oil-bearing sands and sandstones, J. Colloid Interface Sci., 115(1), 9-16, 1987.

Sharma, M.M., and Y.C. Yortsos, Transport of particulate suspensions in porous media: Model formulation, AIChE J., 33(10), 1636-1643, 1987a.

Sharma, M.M., and Y.C. Yortsos, A network model for deep bed filtration processes, AIChE J., 33(10), 1644-1653, 1987b.

Sharma, M.M., and Y.e. Yortsos, Fine migration in porous media, AIChE J., 33(10),1654-1662,1987c.

Sharma, M.M., H. Chamoun, D.S.H.R Sarma, and RS. Schechter, Factors controlling the hydrodynamic detachement of particles from surfaces, J. Colloid Interface Sci., 149(1), 121-134, 1992.

Shaw, D.J., Electrophoresis, Academic Press, New York, Chapter 3, 1969. Sherard, J.L., RS. Decker, and N.L. Ryker, Piping of earth dams of dispersive

clays, Proc. ASCE Speciality Con! on Earth and Earth Supported Structures, 1(1),589-626,1972.

Sherard, J.L., L.P. Dunnigan and J.R Talbot, Filters for silts and clays, J. Geotech. Engin. Div., ASCE, 110(6),701-719,1984.

Simon, R, and F.J. Kelsey, The use of capillary tube networks in reservoir performance studies - I, Soc. Pet. Engin. J., June, 99-112, 1971.

Simon, R., and F.J. Kelsey, The use of capillary tube networks in reservoir performance studies - II, Soc. Pet. Engin. J., Aug., 345-351,1972.

Slattery, J.e., Momentum, Energy and Mass Transfer in Continua, McGraw Hill, New York, Chapter 4, 1972.

Sloat, B.F., Field test results with alkaline potassium solutions to stabilize clays permanentlay, SPE Reservoir Engin., May, 143-146,1990.

Smith, C. F., J.P. Pavalich, and RL. Solvinsky, Potassium, calcium treatments inhibit clay swelling, Oil Gas J., Nov. 8~1, 1964.

Solomentsev, Y.E., Y. Pawar, and lL. Anderson, Electrophoretic mobility of nonuniformly charged spherical particles with polarization of the double

166 REFERENCES

layers, J. Colloid Interface Sci., 158, 1-9, 1993. Srinivasan K.R., and H.S. Fogler, Use ofinorgano-organo-clays in the removal

of priority pollutants from industrial wastewaters: Structural aspects, Clays Clay Minerals, 38(3), 277-286, 1990a.

Srinivasan K.R., and H.S. Fogler, Use ofinorgano-organo-clays in the removal of priority pollutants from industrial wastewaters: Adsorption ofbenzo(a) pyrene and chlorophenols from aqueous solutions, Clays Clay Minerals, 38(3),287-293, 1990b.

Svarvsky, L., Solid-liquid Separation Proccess and Technology, Handbook of Powder Technology, Vol. 5., Chapter 4, Elsevier, Amsterdam, 1985.

Swanton, S.W., Modeling colloid transport in ground water: The prediction of colloid stability and retention behaviour, Adv. Colloid Interface Sci., 54, 129-208, 1995.

Swartzen-Allen, S.L., and E. Matijevic, Colloid and surface properties of clay suspensions: Stability of montmorillonite and Kaolinite, J. Colloid Interface Sci., 56(1), 157-167, 1976.

Sydansk, R.D., Discussion of the effects of temperature and confining on single-phase flow in consolidated rocks, J. Pet. Techno/., 32, 1329-1330, 1980.

Sydansk, R.D., Stabilizing clays with potassium hyroxide, J. Pet. Technol., 36, 1366-1374, 1984.

Tan, Y., J. T. Gannon, P. Baveye, and M. Alexander, Transport of bacteria in an aquifer sand: Experiments and model simulations, Water Resour. Res., 30(12),3243-3253,1994.

Thomas, R.L., and C.W. Crowe, Matrix treatment employs new acid system for stimulation and control of fines migration in sandstone formations, J. Pet. Technol., 33, 1491-1500, 1981.

Thomson, G., N. Kallay, and E. Matijevic, Particle adhesion and removal in model systems - IX: Detachment of rod-like ,B-FeOH particles from steel, Chem. Engin. Sci., 39(7/8), 1271-1276, 1984.

Thompson, K.E., Interfacial Reactions for the Modification of Flow in Porous Media, Ph.D. thesis, University of Michigan, 1995.

Tien, C., Granular Filtration of Aerosols and Hydrosols, Butterworth Publishers, Chapter 5, 1989.

Todd, A.c., lE. Somerville, and G. Scott, The application of depth offormation damage measurements in predicting water injectivity decline, SPE 12498, Denver, CO,1984.

Torok, l, L.P. Buckley, and B.L. Woods, The separation of radionuclide

REFERENCES 167

migration by solution and particle transport 1ll soil, J. Contaminant Hydrology, 6, 185--203, 1990.

Tsakiroglou, e.D., and A.C. Payatakes, A new simulator of mercury porisimetry for the characterization of porous materials, J. Colloid Inteiface Sci., 137(2),315--339,1990.

Tsakiroglou, C.D. and A.C. Payatakes, Effects of pore-size correlations on mercury porosimetry curves, J. Colloid Inteiface Sci., 146(2), 479-494, 1991.

Vaidya, R.N., and H.S. Fogler, Formation damage due to colloidally induced fines migration, Colloids Surfaces, 50, 215--229, 1990.

Vaidya, R.N., Fines Migration and Formalation Damage, Ph.D. thesis, The University of Michigan, Ann Arber, 1991.

Valey, e.D., How hydrolyzable metal ions react with clays to control formation water sensitivity, J. Pet. Technol., Sept., 1111-1118, 1969.

van alphen, H., Introduction to Clay Colloid Chemistry, John Wiley and Sons, New York, Appendix-II, 1977.

van ass, C.J., M.K. Chaudhary, and R.J. Goed, Interfacialliftshitz- van der Waals and polar interactions in macroscopic systems, Chem. Rev., 88, 927-941, 1988.

van ass, C.J., Interfacial Forces in Aqueous Media, Marcel Dekker, Inc., New York, Chapter 1, 1994.

Visser, J. in Surface and Colloid Science, E. Matijevic Ed., Chapter 8, Wiley, New York, 1976.

Voice, T.e., and W.J. Weber Jr., Sorption of hydrophobic compounds by sediments, soils and suspended solids - I, Theory and background, Water Res., 17(10), 1433-1441,1983.

Voice, T.C., C.P. Rice, and W.J. Weber Jr., Eftect of solid concentration on sorptive partitioning of hydrophobic pollutants in aquatic systems, Environ. Sci. Tech., 17(9), 513-517, 1983.

Vrbanac, M.D., and J.e. Berg, The use of wetting measurements in the assessment of acid-base interactions at solid-liquid interfaces, Acid-Base Interactions at Solid-Liquid Interfaces, Ed. by Mittal K.L and H.R. Anderson, Jr. VSP, 67-78, 1991.

Weber Jr., W.J., T.J. Voice, M. Pirbazari, G.B. Hunt, and D. Ulanoft, Sorption of hydrophobic compounds by sediments, soils and suspended solids - II Sorbent evaluation studies, Water Res., 17, P 1443-1452, 1983.

Wiese, G.R., and T.W. Healy, Effect of particle size on colloid stability, Trans. Faraday Soc., 66, 490-499,1970.

168 REFERENCES

Williams, D.J.A., and K.P. Williams, Electrophoresis and zeta potential of kaolinite, J Colloid Interface Sci., 65(1), 79-'(,7, 1978.

Xu, Z. and R Yoon, The role of hydrophobic interactions in coagulation, J Colloid Interface Sci., 132(2),532-541, 1989.

Yanuka, M, F.A.L. Dullien, and D.E. Elricgh, Serial sectioning and digitization of porous media for two- and three- dimensional analysis and reconstruction, J Micro Sci., 135, 159-168, 1984.

Yao, K., M.T. Habibian, and C.R. O'Melia, Water and waste-water filtration: Concepts and applications, Environ. Sci. Technol., 5(11),1105-1172,1971.

Young, B.M., H.C. McLaughlin, and J.K. Borchardt, Clay stabilization agents - their effectiveness in high temperature steam,J Pet. Techno!., Dec. 2121-2131,1980.

Zahka, J., and L. Mir, Ultrafication of Latex emulations, Chern. Engin. Prog., 73(12),53-55, 1977.

Zaltoun A. and N. Berton, Stabilization of montmorillonite clay in porous media by high molecualr weight polymers, SPE Production Engin., May, 160-166, 1993.

A

AB interaction, 36 acidization, 2 adhesive force, 65, 66 attapulgite, 22

B

bacteria, 5 Berea sandstone, 2, 20, 23, lO6 Bethe lattice, 11 Biocolloidal contaminants, 148 biocolloidal fines, 5, 26 Boltzman constant, 32 bonds, 114 Born repulsive potential, 36 Brownian fines, 55

c cake filtration, 8 capture coefficient, 82, 95, 98 cation exchange capacity, 24 cationic organic polymers, 140 charge regulation models, 39 Chemical characterization, 17, 26 chemical methods, 136 clay particles, 2, 20 clay stabilization, 133 Colloidal characterization, 16, 23 colloidally induced release, 29 Constant charge, 32 Constant potential, 32 contact deformation, 66 contamination of soils, 5 convective jamming, 95

INDEX

169

coordination number, 11, 13, 74, lO9, 115

critical flow velocity, 67, 69, 93 critical particle concentration, 75, 83,

87 critical rate of salinity decrease, 79, 88 critical salt concentration, 46, 93 critical shear stress, 67, 69 critical total ionic strength, 51 crystalline regime, 54

D

Darcy's law, 14,82 deep bed filtration, 7 direct interception, 95 DLVO theory, 44 double layer repulsion, 29, 40 drilling, 2

E

effective medium approximation, 118 electro-kinetic interactions, 48 energy barrier, 46, 55 entrapment, 7, 73, 74, 103 erosion rate coefficient, 70, 71

F

facilitated contaminant transport, 144 fine particles, 1 fines, 19 Fokker-Plank equation, 55 force of detachment, 136

170

G

ground water pollution, 5

H

Hagen-Poiseuille, 120 Hamaker constant, 33, 35 hydrodynamic detachment, 63 hydrodynamic forces, 64 hydrodynamically induced release, 29 hydrolyzable metal ions, 139 hydrophobic interaction, 37 hydroxyl-aluminum, 140

I

illite, 20,21,26 interaction force boundary layer, 56 interconnectivity,74, 115 ion exchange, 52

K

kaolinite, 20, 21, 26,52

L

lattice arrangement, 115 leaching of polycations, 52 Lifshitz theory, 34 lift force, 37, 64 London-van der Waals, 29, 33, 40

M

mass balance for the fine particles in the suspension, 81

mica, 20 micro-organisms, 5, 148 microquake, 54 migration of biocolloidal fines, 141,

149

INDEX

migration of fine particles, 1,3,5 migratory fines, 19,25 Monod equation, 149 montmorillonite, 20, 26 moving permeability front, 93 multiparticle bridging, 95

N

Network models, 114, 117, 128 nodes, 114 non-Brownian particles, 55

o osmotic regime, 54

p

percentage of calcium, 50 permeability, 14,83, 101, 103 permeability reduction, 89, 102, 106,

109 physical method of attachment, 134 physically representative network, 131 piping, 3, 4, 73, 75, 76, 79 plugging, 3, 7, 73, 76, 78, 79, 103 Poisson-Boltzman equation, 31 Pollution, 5 pore, 9 pore chamber size distribution, 10

pore chambers, 10, 11 pore closure, 98

pore constriction size distribution, 10, 11

pore constrictions, 10, 11 pore size distribution, 13

pore structure, 74 porosity, 14,80, 83, 84

porous media, 1, 9, 74 primary minimum, 40, 41, 54

INDEX

R

Rate expressions for release offine par-ticles,96

rate of capture, 82 rate of erosion, 70 release and capture mechanisms, 91 release coefficient, 56, 59, 61, 109 retarded interaction, 34

s Sand bed filters, 87 sand control, 135 saponite, 22 secondary minimum, 41, 54 sequential reduction in permeabi1ity,

93 size exclusion, 95 Smoluchowski's equation, 55 soil erosion, 84, 136 soil microflora, 19 sorption coefficient, 142 sorption of hydrophobic compounds,

142 specific characteristics of cation, 48 Stevens sandstone, 46 streaming potential, 16 surface charge, 17,23,24 surface erosion, 4 surface potentials, 39 surface roughness, 15 swelling clays, 54

171

T

total interaction energy, 39, 41 total mobile concentration of contami­

nant, 148 trajectory calculations, 130 tunnel erosion, 3, 4

u Unconsolidated porous media, 10

v viruses, 5 void fraction, 10

w washout, 7 water flooding, 2 Water sensitivity, 2 water sensitivity, 2, 3, 88 water shock, 2 wettability, 15 wrap-around boundary conditions, 122

z zeta potential, 16,24,25,48

Theory and Applications of Transport in Porous Media

Series Editor: Jacob Bear, Technion -Israel Institute o/Technology, Haifa, Israel

1. H.1. Ene and D. Polissevski: Thermal Flow in Porous Media. 1987 ISBN 90-277-2225-0

2. J. Bear and A. Verruijt: Modeling Groundwater Flow and Pollution. With Computer Programs for Sample Cases. 1987 ISBN 1-55608-014-X; Pb 1-55608-015-8

3. G.I. Barenblatt, V.M. Entov and V.M. Ryzhik: Theory o/Fluid Flows ThroughNatural Rocks. 1990 ISBN 0-7923-0167-6

4. J. Bear and Y. Bachmat: Introduction to Modeling o/Transport Phenomena in Porous Media. 1990 ISBN 0-7923-0557-4; Pb (1991) 0-7923-1106-X

5. J. Bear and J-M. Buchlin (eds.): Modelling and Applications o/Transport Phenomena in Porous Media. 1991 ISBN 0-7923-1443-3

6. Ne-Zheng Sun: Inverse Problems in Groundwater Modeling. 1994 ISBN 0-7923-2987-2

7. A. Verruijt: Computational Geomechanics. 1995 ISBN 0-7923-3407-8

8. V.N. Nikolaevskiy: Geomechanics and Fluidodynamics. With Applications to Reser-voir Engineering. 1996 ISBN 0-7923-3793-X

9. V.1. Selyakov and V.V. Kadet: Percolation Models for Transport in Porous Media. With Applications to Reservoir Engineering. 1996 ISBN 0-7923-4322-0

10. J.H. Cushman: The Physics 0/ Fluids in Hierarchical Porous Media: Angstroms to Miles. 1997 ISBN 0-7923-4742-0

11. J.M. Cralet and M. EI Hatri (eds.): Recent Advances in Problems 0/ Flow and Transport in Porous Media. 1998 ISBN 0-7923-4938-5

12. K.C. Khilar and H.S. Fogler: Migration o/Fines in Porous Media. 1998 ISBN 0-7923-5284-X

Kluwer Academic Publishers - Dordrecht / Boston / London