Thixotropy

Jan Mewis; Norman J. Wagner

doi:10.1017/CBO9780511977978.010

7 - Thixotropy

Published online by Cambridge University Press: 05 December 2011

Jan Mewis and

Norman J. Wagner

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Jan Mewis: Affiliation:
Katholieke Universiteit Leuven, Belgium
Norman J. Wagner: Affiliation:
University of Delaware

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Summary

Introduction

In earlier chapters it was shown that Brownian motion and colloidal interparticle forces give rise to viscoelastic effects. When a constant shear rate is applied to some colloidal suspensions, the viscosity can exhibit long transients, while viscoelastic features such as normal stress differences are hardly detectable. A well-known daily life example is provided by tomato ketchup: shaking turns it from a gel-like substance into a free-flowing liquid, but when left alone it will gradually stiffen and return to a gel. This is an example of the more general phenomenon known as thixotropy. It has been reported for a large number of colloidal products, some of which are listed in Table 7.1. They are most often colloidal glasses or gels at rest. Extensive lists of thixotropic products can be found in the literature [1–4]. Some products are actually formulated to exhibit a well-defined time evolution for viscosity recovery after shearing. Special additives (“thixotropic agents”) are available to induce and control such behavior. We note that many complex fluids such as some polymeric systems, liquid crystals and micellar systems exhibit thixotropy; however, these interesting materials are beyond our scope.

There is an extensive body of papers on thixotropy, scattered over the scientific and technical literature, including some reviews [1–5]. Nevertheless, the subject has been essentially ignored in rational continuum mechanics and, until recently, in colloid science. An explanation can perhaps be found in the persistent ambiguity about its definition, the lack of suitable model systems for study, and the complexity of the phenomenon, which includes serious measurement challenges. The more recent interest in glasses and gels within the general area of soft condensed matter is providing new terminology in the field, such as aging and shear rejuvenation [6]. This chapter provides a guide to understanding thixotropy in colloidal suspensions and an introduction to its modeling.

Type: Chapter
Information: Colloidal Suspension Rheology , pp. 228 - 251

DOI: https://doi.org/10.1017/CBO9780511977978.010 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

Bauer, W. H.Collins, E. A.Thixotropy and dilatancyEirich, F. R.Rheology: Theory and Applications, Vol. 4New YorkAcademic Press 1967 423CrossRef Google Scholar

Mewis, J.Thixotropy: A general reviewJ Non-Newtonian Fluid Mech 6 1979 1CrossRef Google Scholar

Barnes, H. A.Thixotropy: A reviewJ Non-Newtonian Fluid Mech 70 1997 1CrossRef Google Scholar

Mewis, J.Wagner, N. J.ThixotropyAdv Colloid Interface Sci 147–148 2009 214CrossRef Google Scholar PubMed

Coussot, P.Rheophysics of pastes: A review of microscopic modelling approachesSoft Matter 3 2007 528CrossRef Google Scholar

Cipelletti, L.Ramos, L.Slow dynamics in glassy soft matterJ Phys: Condens Matt 17 2005 R253Google Scholar

http://goldbook.iupac.org

Schalek, E.Szegvari, A.Ueber EisenoxydgallertenKolloid-Z 32 1923 318CrossRef Google Scholar

Peterfi, T.Das mikrurgische VerfahrenNaturwissenschaften 11 1923 81CrossRef Google Scholar

Schalek, E.Szegvari, A.Die langsame Koaguation konzentrierter Esenoxydsole zu reversiblen GallertenKolloid-Z 32 1923 326CrossRef Google Scholar

Freundlich, H.ThixotropieParisHermann 1935Google Scholar

Scott-Blair, G. W.An Introduction to Industrial RheologyLondonJ. & A. Churchill 1938Google Scholar

Green, H.Industrial Rheology and Rheological StructuresNew YorkJohn Wiley & Sons 1949Google Scholar

Goodeve, C. F.A general theory of thixotropy and viscosityTrans Faraday Soc 35 1939 342CrossRef Google Scholar

Cheng, D. C.-H.Evans, F.Phenomenological characterization of the rheological behaviour of inelastic reversible thixotropic and antithixotropic fluidsBrit J Appl Phys 16 1965 1599CrossRef Google Scholar

Keller, D. S.Keller, J. D. V.An investigation of the shear thickening and antithixotropic behavior of concentrated coal-water dispersionsJ Rheol 34 1990 1267CrossRef Google Scholar

Potanin, A. A.Thixotropy and rheopexy of aggregated dispersions with wetting polymerJ Rheol 48 2004 1279CrossRef Google Scholar

Freundlich, H.Juliusburger, F.Thixotropy, influenced by the orientation of anisometric particles in sols and suspensionsTrans Faraday Soc 31 1935 920CrossRef Google Scholar

Quemada, D.Rheological modeling of complex fluids: 4. Thixotropic and thixoelastic behaviour – Start-up and stress relaxation, creep tests and hysteresis cyclesEur Phys J Appl Phys 5 1999 191CrossRef Google Scholar

Green, H.Weltmann, R. N.Analysis of the thixotropy of pigment-vehicle suspensions: Basic principles of the hysteresis loopInd Eng Chem Anal Ed 15 1943 201CrossRef Google Scholar

Green, H.High-speed rotational viscometer of wide range: Confirmation of the Reiner equation of flowInd Eng Chem Anal Ed 14 1942 576CrossRef Google Scholar

Mylius, E.Reher, E. O.Modelluntersuchungen zur Charakterisieriung thixotroper Medien und ihre Anwendung für verfahrenstechnische ProzessberechnungnenPlaste und Kautschuk 19 1972 420Google Scholar

Dullaert, K.Constitutive Equations for Thixotropic DispersionsKatholieke Universiteit Leuven 2005Google Scholar

Bird, R. B.Marsh, B. D.Viscoelastic hysteresis: I. Model predictionsTrans Soc Rheol 12 1968 479CrossRef Google Scholar

Van der Aerschot, E.Reologie van Reversiebel Geflocculeerde DispersiesKatholieke Universiteit Leuven 1989Google Scholar

Coussot, P.Tabuteau, H.Chateau, X.Ageing and solid or liquid behavior in pastesJ Rheol 50 2006CrossRef Google Scholar

Manley, S.Davidovitch, B.Davies, N. R.Time-dependent strength of colloidal gelsPhys Rev Lett 95 2005CrossRef Google Scholar PubMed

Willenbacher, N.Unusual thixotropic properties of aqeous dispersions of laponite RDJ Colloid Interface Sci 182 1996 501CrossRef Google Scholar

Mewis, J.Spaull, A. J. B.Helsen, J.Structural hysteresisNature 253 1975 618CrossRef Google Scholar

Coussot, P.Leonov, A. I.Piau, J.-M.Rheology of concentrated dispersed systems in a low-molecular-weight matrixJ Non-Newtonian Fluid Mech 46 1993 179CrossRef Google Scholar

Mujumbar, A.Beris, A. N.Metzner, A. B.Transient phenomena in thixotropic systemsJ Non-Newtonian Fluid Mech 102 2002 157CrossRef Google Scholar

Dullaert, K.Mewis, J.A structural kinetics model for thixotropyJ Non-Newtonian Fluid Mech 139 2006 21CrossRef Google Scholar

Pignon, F.Magnin, A.Piau, J.-M.Thixotropic behavior of clay dispersions: Combinations of scattering and rheometric techniquesJ Rheol 42 1998 1349CrossRef Google Scholar

Varadan, P.Solomon, M. J.Shear-induced microstructural evolution of a thermoreversible colloidal gelLangmuir 17 2001 2918CrossRef Google Scholar

Woutersen, A. T. J. M.May, R. P.de Kruif, C. G.The shear-distorted microstructure of adhesive hard-sphere dispersions: A small-angle neutron-scattering studyJ Rheol 37 1993 71CrossRef Google Scholar

Letwimolnun, W.Vergnes, B.Ausias, G.Carreau, P. J.Stress overshoots of organoclay nanocomposites in transient shear flowJ Non-Newtonian Fluid Mech 141 2007 167CrossRef Google Scholar

Solomon, M. J.Almusallam, A. S.Seefeldt, K. F.Somwangthanaroj, A.Varadan, P.Rheology of polypropylene/clay hybrid materialsMacromolecules 34 2001 1864CrossRef Google Scholar

Vermant, J.Ceccia, S.Dolgovskij, M. K.Maffetone, P. L.Macosko, C. W.Quantifying dispersion of layered nanocomposites via melt rheologyJ Rheol 51 2007 429CrossRef Google Scholar

Goddard, J. D.Dissipative materials as models of thixotropy and plasticityJ Non-Newtonian Fluid Mech 14 1984 141CrossRef Google Scholar

Stickel, J. J.Phillips, R. J.Powell, R. L.A constitutive model for microstructure and total stress in particulate suspensionsJ Rheol 50 2006 379CrossRef Google Scholar

Goddard, J. D.A dissipative anisotropic fluid model for non-colloidal particle dispersionsJ Fluid Mech 568 2006 1CrossRef Google Scholar

Burgos, G. M.Alexandrou, A. N.Entov, V.Thixotropic rheology of semisolid metal suspensionsJ Mater Process Technol 110 2001 164CrossRef Google Scholar

Larson, R. G.Constitutive Equations for Polymer Melts and SolutionsBostonButterworths 1988Google Scholar

Frederickson, A. G.A model for the thixotropy of suspensionsAIChE J 16 1970 436CrossRef Google Scholar

Dullaert, K.Mewis, J.Stress jumps on weakly flocculated dispersions: Steady state and transient resultsJ Colloid Interface Sci 287 2005 542CrossRef Google Scholar PubMed

Tiu, C.Boger, D. V.Complete rheological characterization of time-dependent food productsJ Text Stud 5 1974 329CrossRef Google Scholar

Houska, M.Inzenyrske Aspekty Reologie Tixotropnich KapalinTechnical University in Prague 1980Google Scholar

Phan Thien, N.Tanner, R. I.A new constitutive equation derived from network theoryJ Non-Newtonian Fluid Mech 2 1977 353CrossRef Google Scholar

Yziquel, F.Carreau, P. J.Moan, M.Tanguy, P. A.Rheological modeling of concentrated colloidal suspensionsJ Non-Newtonian Fluid Mech 86 1999 133CrossRef Google Scholar

Kemblowski, Z.Petera, J.A generalized rheological model of thixotropic materialsRheol Acta 19 1980 529CrossRef Google Scholar

Lin, S. F.Brodkey, R. S.Rheological properties of slurry fuelsJ Rheol 29 1985 147CrossRef Google Scholar

Pinder, K. L.Time-dependent rheology of the tetrahydrofuran-hydrogen sulphide gas hydrate slurryCan J Chem Eng 42 1964 132CrossRef Google Scholar

Russel, W. B.Saville, D. A.Schowalter, W. R.Colloidal DispersionsCambridgeCambridge University Press 1989CrossRef Google Scholar

Mobuchon, C.Carreau, P. J.Heuzey, M.-C.Effect of flow history on the structure of a non-polar polymer/clay nanocomposite model systemRheol Acta 46 2007 1045CrossRef Google Scholar

van de Ven, T. G. M.Mason, S. G.Microrheology of colloidal dispersions: 8. Effect of shear on perikinetic doublet formationColloid Polym Sci 255 1977 794CrossRef Google Scholar

Slibar, A.Paslay, P. R.On the analytical description of the flow of thixotropic materialsReiner, M.Abir, D.Second-Order Effects in Elasticity, Plasticity and Fluid DynamicsOxfordPergamon Press 1964 314Google Scholar

Harris, J.A continuum theory of time-dependent inelastic flowRheol Acta 6 1967 6CrossRef Google Scholar

Montes, S.White, J. L.Rheological models of rubber-carbon black compounds: Low interaction viscoelastic models and high interaction thixotropic-plastic-viscoelastic modelsJ Non-Newtonian Fluid Mech 49 1993 277CrossRef Google Scholar

Suetsugu, Y.White, J. L.A theory of thixotropic plastic viscoelastic fluids with a time-dependent yield surface and its comparison to transient and steady-state experiments on small particle filled polymer meltsJ Non-Newtonian Fluid Mech 14 1984 121CrossRef Google Scholar

Sobhanie, M.Isayev, A. I.Modeling and experimental investigation of shear flow of a filled polymerJ Non-Newtonian Fluid Mech 85 1999 189CrossRef Google Scholar

Toorman, E. A.Modelling the thixotropic behaviour of dense cohesive sediment suspensionsRheol Acta 36 1997 56CrossRef Google Scholar

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7 - Thixotropy

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