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Rheologica Acta

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01-10-2009 | Original Contribution

A review of microstructure in concentrated suspensions and its implications for rheology and bulk flow

Author: Jeffrey F. Morris

Published in: Rheologica Acta | Issue 8/2009

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Abstract

An overview of present understanding of microstructure in flowing suspensions is provided. An emphasis is placed on how the microstructure leads to observable bulk flow phenomena unique to mixtures. The bridge between the particle and bulk scales is provided by the mixture rheology; one focus of the review is on work that addresses the connection between microstructure and rheology. The non-Newtonian rheology of suspensions includes the well-known rate dependences of shear thinning and thickening, which have influence on bulk processing of suspensions. Shear-induced normal stresses are also measured in concentrated suspensions and include normal stress differences, and the isotropic particle pressure. Normal stresses have been associated with shear-induced migration, and thus have influence on the ultimate spatial distribution of solids, as well as the flow rate during processing; a second focus is on these uniquely two-phase behaviors and how they can be described in terms of the bulk rheology. An important bulk fluid mechanical consequence of normal stresses is their role in driving secondary flows.

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Abbott JR, Tetlow N, Graham AL, Altobelli SA, Fukushima E, Mondy LA, Stephens TS (1991) Experimental observations of particle migration in concentrated suspensions: Couette flow. J Rheol 35:773CrossRefADS

Ackerson BJ (1990) Shear induced order and shear processing of model hard-sphere suspensions. J Rheol 34:553CrossRefADS

Aidun CK, Lu Y, Ding EJ (1998) Direct analysis of particulate suspensions with inertia using the discrete Boltzmann equation. J Fluid Mech 373:287CrossRefADS

Altobelli SA, Givler RC, Fukushima E (1991) Velocity and concentration measurements of suspensions by nuclear magnetic resonance imaging. J Rheol 35:721CrossRefADS

Ball RC, Melrose JR (1995) Lubrication breakdown in hydrodynamic simulations of concentrated colloids. Adv Colloid Interface Sci 59:19CrossRef

Barnes HA (1989) Shear-thickening (dilatancy) in suspensions of nonaggregating solid particles dispersed in Newtonian liquids. J Rheol 33:329CrossRefADS

Banchio AJ, Brady JF (2003) Accelerated Stokesian Dynamics: brownian motion. J Chem Phys 118:10323CrossRefADS

Batchelor GK (1970) The stress system in a suspension of force-free particles. J Fluid Mech 41:545CrossRefADSMathSciNet

Batchelor GK (1977) The effect of Brownian motion on the bulk stress in a suspension of spherical particles. J Fluid Mech 83:97CrossRefADSMathSciNet

Batchelor GK, Green JT (1972a) The hydrodynamic interation of two small freely-moving spheres in a linear flow field. J Fluid Mech 56:375CrossRefADS

Batchelor GK, Green JT (1972b) Determination of bulk stress in a suspension of spherical-particles to order c ². J Fluid Mech 56:401CrossRefADS

Bender JW, Wagner NJ (1995) Optical measurement of the contributions of colloidal forces to the rheology of concentrated colloidal dispersions. J Colloid Interface Sci 172:171CrossRef

Bender JW, Wagner NJ (1996) Reversible shear thickening in monodisperse and bidisperse colloidal dispersions. J Rheol 40:899CrossRefADS

Bergenholtz J (2001) Theory of rheology of colloidal dispersions. Curr Opin Colloid Interface Sci 6:484CrossRef

Bergenholtz J, Brady JF, Vicic MA (2002) The non-Newtonian rheology of dilute colloidal suspensions. J Fluid Mech 456:239CrossRefADS

Bossis G, Meunier A, Brady JF (1991) Hydroynamic stress on fractal aggregates of spheres. J Chem Phys 94:5064CrossRefADS

Brader JM, Cates ME, Fuchs M (2008) First-principles constitutive equation for suspension rheology. Phys Rev Lett 101:138301PubMedCrossRefADS

Brady JF, Morris JF (1997) Microstructure of strongly sheared suspensions and its impact on rheology and diffusion. J Fluid Mech 348:103CrossRefADS

Brady JF, Vicic MA (1995) Normal stresses in colloidal dispersions. J Rheol 39:545CrossRefADS

Brady JF, Bossis G (1988) Stokesian Dynamics. Ann Rev Fluid Mech 20:111CrossRefADS

Butler JE, Majors PD, Bonnecaze RT (1999) Observations of shear-induced particle migration for oscillatory flow of a suspension within a tube. Phys Fluids 11:2865CrossRefADS

Chang CY, Powell RL (1993) Dynamic simulation of bimodal suspensions of hydrodynamically interacting spherical particles. J Fluid Mech 253:1CrossRefADS

Chow AW, Iwayima JH, Sinton SW, Leighton DT (1995) Particle migration of non-Brownian, concentrated suspensions in a truncated cone-and-plate. Soc. Rheology Mtg, Sacramento

Davis RH, Zhao Y, Galvin KP, et al (2003) Solid-solid contacts due to surface roughness and their effects on suspension behaviour. Phil Trans R Soc Lond A 361:871CrossRefADSMathSciNet

Deboeuf A, Gauthier G, Martin J, Yurkovetsky Y, Morris JF (2009) Particle pressure in a sheared suspension: a bridge from osmosis to granular dilatancy. Phys Rev Lett 102:108301

D’Haene P, Mewis J, Fuller GG (1993) Scattering dichroism measurements of flow-induced structure of a shear thickening suspension. J Colloid Interface Sci 156:350CrossRef

Dhont JKG, Briels WJ (2008) Vorticity and gradient banding. Rheol Acta 47:257CrossRef

Doi M, Edwards SF (1988) The theory of polymer dynamics. Oxford Science, Oxford

Drew DA, Lahey RT (1993) Analytical modeling of multiphase flow. In: Roco MC (ed) Particulate two-phase flows. Butterworth-Heinemann, Oxford

Foss DR, Brady JF (2000) Structure, diffusion and rheology of Brownian suspensions by Stokesian Dynamics simulation. J Fluid Mech 407:167CrossRefADS

Frank M, Anderson D, Weeks ER, Morris JF (2003) Particle migration in pressure-driven flow of a Brownian suspension J Fluid Mech 493:363CrossRefADS

Fuchs M, Cates ME (2002) Theory of nonlinear rheology and yielding of dense colloidal suspensions. Phys Rev Lett 89:248304PubMedCrossRefADS

Giesekus H (1965) Sekundarstromungen in viskoelastischen Flussigkeiten bei stationarer und periodischer Bewegung. Rheol Acta 4:85CrossRef

Goddard JD (1984) Dissipative materials as models of thixotropy and plasticity. J Non-Newton Fluid Mech 14:141CrossRef

Goddard JD (2006) A dissipative anisotropic fluid model for non-colloidal particle dispersions. J Fluid Mech 568:1CrossRefADSMathSciNet

Hammond PS (1995) Settling and slumping in a Newtonian slurry, and implications for proppant placement during hydraulic fracturing of gas wells. Chem Eng Sci 50:3247CrossRef

Hoffman RL (1972) Discontinuous and dilatant viscosity behavior in concentrated suspensions. I. Observation of a flow instability. Trans Soc Rheol 16:155CrossRef

Jeffrey DJ, Morris JF, Brady JF (1993) The pressure moments for two spheres in a low-Reynolds-number flow. Phys Fluids A 5:2317CrossRefADS

Jeffrey DJ, Onishi Y (1984) Calculation of the resistance and mobility functions for two unequal rigid spheres in low-Reynolds-number flow. J Fluid Mech 139:261CrossRefADS

Jenkins JT, McTigue DF (1990) Transport process in concentrated suspensions: the role of particles fluctuations. In: Joseph DD, Schaeffer DG (eds) Two phase flows and waves. Springer, New York

Jomha A, Reynolds P (1993) An experimental study of the first normal stress difference-shear stress relationship in simple shear flow for concentrated shear thickening suspensions. Rheol Acta 32:457CrossRef

Keller DS, Keller DV (1991) The effect of particle-size distribution on the antithixotropic and shear thickening properties of coal-water dispersions. J Rheol 35:1583CrossRefADS

Koh CJ, Hookham P, Leal LG (1994) An experimental investigation of concentrated suspension flows in a rectangular channel. J Fluid Mech 266:1CrossRefADS

Kolli VG, Pollauf EJ, Gadala-Maria F (2002) Transient normal stress response in a concentrated suspension of spherical particles. J Rheol 46:321CrossRefADS

Krieger IM (1972) Rheology of monodisperse latices. Adv Colloid Interface Sci 3:111CrossRef

Kulkarni SD, Morris JF (2009) Ordering transition and structural evolution under shear in Brownian suspensions. J Rheol 53:417CrossRefADS

Ladd AJC, Verberg R (2001) Lattice-Boltzmann simulations of particle-fluid suspensions. J Stat Phys 104:1191CrossRefMathSciNet

Laun H (1994) Normal stresses in extremely shear thickening polymer dispersions. J Non-Newton Fluid Mech 54:87CrossRef

Leighton DT, Acrivos A (1986) Viscous resuspension. Chem Eng Sci 41:1377CrossRef

Leighton DT, Acrivos A (1987) The shear-induced migration of particles in concentrated suspensions. J Fluid Mech 181:415CrossRefADS

Lionberger RA (1998) Shear thinning of colloidal dispersions. J Rheol 42:843CrossRefADS

Lionberger RA, Russel WB (1997a) Effectiveness of nonequilibrium closures for the many body forces in concentrated colloidal dispersions. J Chem Phys 106(1):402CrossRefADS

Lionberger RA, Russel WB (1997b) A Smoluchowski theory with simple approximations for hydrodynamic interactions in concentrated dispersions. J Rheol 41:399CrossRefADS

Lootens D, Hébraud P, Lécolier E, van Damme H (2004) Gelation, shear-thinning and shear-thickening in cement slurries. Oil Gas Sci Technol 59:31CrossRef

Lootens D, van Damme H, Hémar, Y, Hébraud P (2005) Dilatant flow of concentrated suspensions of rough particles. Phys Rev Lett 95:268302PubMedCrossRefADS

Lyon MK, Leal LG (1998a) An experimental study of the motion of concentrated suspensions in two-dimensional channel flow. Part 1. Monodisperse systems. J Fluid Mech 363:25CrossRefADS

Lyon MK, Leal LG (1998b) An experimental study of the motion of concentrated suspensions in two-dimensional channel flow. Part 2. Bidisperse systems. J Fluid Mech 363:57CrossRefADS

MacMeccan RM, Clausen JR, Neitzel GP, Aidun CK (2009) Simulating deformable particle suspensions using a coupled lattice-Boltzmann and finite-element method. J Fluid Mech 618:13CrossRefADSMathSciNet

Maranzano BJ, Wagner NJ (2002) Flow-small angle neutron scattering measurements of colloidal dispersion microstructure evolution through the shear thickening transition. J Chem Phys 117:10291CrossRefADS

Martys NS (2005) Study of a dissipative particle dynamics based approach for modeling suspensions. J Rheol 49:401CrossRefADS

Melrose JR, Ball RC (2004a) Continuous shear thickening transitions in model concentrated colloids—The role of interparticle forces. J Rheol 48:937CrossRefADS

Melrose JR, Ball RC (2004b) “Contact networks” in continuously shear thickening colloids. J Rheol 48:961CrossRefADS

Miller RM, Morris JF (2006) Normal stress-driven migration and axial development in pressure-driven flow of a concentrated suspension. J Non-Newton Fluid Mech 135:149CrossRef

Moraczewski T, Tang HY, Shapley NC (2005) Flow of a concentrated suspension through an abrupt axisymmetric expansion measured by nuclear magnetic resonance imaging. J Rheol 49:1409CrossRefADS

Morris JF, Boulay F (1999) Curvilinear flows of noncolloidal suspensions: the role of normal stresses. J Rheol 43:1213CrossRefADS

Morris JF, Brady JF (1998) Pressure-driven flow of a suspension: buoyancy effects. Int J Multiphase Flow 24:105CrossRef

Morris JF, Katyal B (2002) Microstructure from simulated Brownian suspension flow at large shear rate. Phys Fluids 14:1920CrossRefADS

Newstein MC, Wang H, Balsara NP, et al (1999) Microstructural changes in a colloidal liquid in the shear thinning and shear thickening regimes. J Chem Phys 111:4827CrossRefADS

Nguyen QD, Boger DV (1998) Application of rheology to solving tailings disposal problems. Int J Mineral Process 54:217CrossRef

Norman JT, Oguntade BO, Bonnecaze RT (2008) Particle-phase distributions of pressure-driven flows of bidisperse suspensions. J Fluid Mech 594:1CrossRefADS

Nott PR, Brady JF (1994) Pressure-driven flow of suspensions: simulation and theory. J Fluid Mech 275:157CrossRefADS

Ovarlez G, Bertrand F, Rodts S (2006) Local determination of the constitutive law of a dense suspension of noncolloidal particles through magnetic resonance imaging. J Rheol 50:259CrossRefADS

Parsi F, Gadala-Maria F (1987) Fore-and-aft asymmetry in a concentrated suspension of solid spheres. J Rheol 31:725CrossRefADS

Phung TN, Brady JF, Bossis G (1996) Stokesian Dynamics simulation of brownian suspensions. J Fluid Mech 313:181CrossRefADS

Pine DJ, Gollub JP, Brady JF, Leshansky AM (2005) Chaos and threshold for irreversibility in sheared suspensions. Nature 438:997PubMedCrossRefADS

Prasad D, Kytömaa HK (1995) Particle stress and viscous compaction during shear of dense suspensions. Int J Multiph Flow 21:775CrossRef

Rampall I, Smart J, Leighton DT (1997) The influence of surface roughness on the pair particle distribution function of dilute suspensions of non-colloidal spheres in simple shear flow. J Fluid Mech 339:1CrossRefADS

Ramachandran A, Leighton DT (2007) Viscous resuspension in a tube: the impact of secondary flows resulting from second normal stress differences. Phys Fluids 19:053301CrossRefADS

Ramachandran A, Leighton DT (2008) The influence of secondary flows induced by normal stress differences on the shear-induced migration of particles in concentrated suspensions. J Fluid Mech 603:207CrossRefADSMathSciNet

Russel WB, Saville DA, Schowalter WR (1989) Colloidal dispersions. Cambridge University Press, Cambridge

Semwogerere D, Morris JF, Weeks ER (2007) Development of particle migration in pressuredriven flow of a Brownian suspension. J Fluid Mech 581:437CrossRefADS

Sierou A, Brady JF (2001) Accelerated Stokesian Dynamics simulations. J Fluid Mech 448:115CrossRefADS

Sierou A, Brady JF (2002) Rheology and microstructure in concentrated noncolloidal suspensions. J Rheol 46:1031CrossRefADS

Singh A, Nott PR (2000) Normal stresses and microstructure in bounded sheared suspensions via Stokesian Dynamics simulations. J Fluid Mech 412:279CrossRefADS

Singh A, Nott PR (2003) Experimental measurements of the normal stresses in sheared Stokesian suspensions. J Fluid Mech 490:293CrossRefADS

Stickel JJ, Phillips RJ, Powell RL (2006) A constitutive model for microstructure and total stress in particulate suspensions. J Rheol 50:379CrossRefADS

Stickel JJ, Phillips RJ, Powell RL (2007) Application of a constitutive model for particulate suspensions: time-dependent viscometric flows. J Rheol 51:1271CrossRefADS

Stickel JJ, Powell RL (2005) Fluid mechanics and rheology of dense suspensions. Ann Rev Fluid Mech 37:129CrossRefADSMathSciNet

Subia SR, Ingber MS, Mondy LA, Altobelli SA, Graham AL (1998) Modelling of concentrated suspensions using a continuum constitutive equation. J Fluid Mech 373:193CrossRefADS

van der Werff JC, de Kruif CG (1989) Hard-sphere colloidal dispersions: the scaling of rheological properties with particle size, volume fraction, and shear rate. J Rheol 33:421CrossRef

Vieira SL, Neto LBP, Arruda ACF (2000) Transient behavior of an electrorheological fluid in shear flow mode. J Rheol 44:1139CrossRefADS

von Pfeil K, Graham MD, Klingenberg DJ, Morris JF (2002) Pattern formation in flowing electrorheological fluids. Phys Rev Lett 88:188301CrossRefADS

Wilson HJ (2005) An analytic form for the pair distribution function and rheology of a dilute suspension of rough spheres in plane strain flow. J Fluid Mech 534:97CrossRefADSMathSciNet

Xi CG, Shapley NC (2008) Flows of concentrated suspensions through an asymmetric bifurcation. J Rheol 52:625CrossRefADS

Yurkovetsky Y, Morris JF (2006) Triplet correlation in sheared suspensions of Brownian particles. J Chem Phys 124:204908PubMedCrossRefADS

Yurkovetsky Y, Morris JF (2008) Particle pressure in a sheared Brownian suspension. J Rheol 52:141CrossRefADS

Yziquel F, Carreau PJ, Moan M, Tanguy PA (1999) Rheological modeling of concentrated colloidal suspensions. J Non-Newton Fluid Mech 86:133CrossRef

Zarraga IE, Hill DA, Leighton DT (2000) The characterization of the total stress of concentrated suspensions of noncolloidal spheres in Newtonian fluids. J Rheol 44:185CrossRefADS

Zarraga IE, Hill DA, Leighton DT (2001) Normal stresses and free surface deformation in concentrated suspensions of noncolloidal spheres in a viscoelastic fluid. J Rheol 45:1065CrossRefADS

Title: A review of microstructure in concentrated suspensions and its implications for rheology and bulk flow
Author: Jeffrey F. Morris
Publication date: 01-10-2009
Publisher: Springer-Verlag
Published in: Rheologica Acta / Issue 8/2009
Print ISSN: 0035-4511
Electronic ISSN: 1435-1528
DOI: https://doi.org/10.1007/s00397-009-0352-1

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