2013
DOI: 10.1122/1.4798626
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Rheology of viscoelastic suspensions of spheres under small and large amplitude oscillatory shear by numerical simulations

Abstract: The dynamic response of a viscoelastic suspension of spheres under small and large amplitude oscillatory shear is investigated by three-dimensional direct numerical simulations. A sliding triperiodic domain is implemented whereby the computational domain is regarded as the bulk of an infinite suspension. A fictitious domain method is used to manage the particle motion. After the stress field is computed, the bulk properties are recovered by an averaging procedure. The numerical method is validated by comparing… Show more

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Cited by 34 publications
(18 citation statements)
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“…Non-Newtonian liquids, for instance, are responsible for complex particle dynamics (D'Avino and Maffettone 2015) that, in turn, alters the suspension rheology as compared to the Newtonian case (Mewis and Wagner 2012). The bulk rheology of suspensions of spheres in non-Newtonian media has been thoroughly investigated at various concentrations (Chan and Powell 1984;Aral and Kalyon 1997;Schaink et al 2000;Haleem and Nott 2009;D'Avino et al 2013). In the limit of dilute suspensions of spheres, the bulk rheology (viscosity, first and second normal stress differences) has been recently examined through theoretical analysis by assuming a weakly viscoelastic suspending medium (Greco et al 2005;Koch and Subramanian 2006;Greco et al 2007;Housiadas and Tanner 2009).…”
Section: Introductionmentioning
confidence: 98%
“…Non-Newtonian liquids, for instance, are responsible for complex particle dynamics (D'Avino and Maffettone 2015) that, in turn, alters the suspension rheology as compared to the Newtonian case (Mewis and Wagner 2012). The bulk rheology of suspensions of spheres in non-Newtonian media has been thoroughly investigated at various concentrations (Chan and Powell 1984;Aral and Kalyon 1997;Schaink et al 2000;Haleem and Nott 2009;D'Avino et al 2013). In the limit of dilute suspensions of spheres, the bulk rheology (viscosity, first and second normal stress differences) has been recently examined through theoretical analysis by assuming a weakly viscoelastic suspending medium (Greco et al 2005;Koch and Subramanian 2006;Greco et al 2007;Housiadas and Tanner 2009).…”
Section: Introductionmentioning
confidence: 98%
“…There are various kinds of standard flows [1][2][3] to study the rheological properties of non-Newtonian fluids which all are similar in basics. In these methods, a material is subjected to defined stress or strain, and then, its response to the imposed stress or strain is measured.…”
Section: Introductionmentioning
confidence: 99%
“…The situation gets even more difficult if the suspending fluid is viscoelastic, where effects such as particle alignment [10,11] and particle migration [12,13] might play a role in the rheology. Suspensions in viscoelastic fluids have been studied both experimentally [14,15] and computationally [16,17] (an extensive overview was given recently in [18]), yet a full understanding is lacking. For example in a highly elastic Boger fluid, typical particle dynamics observed in viscoelastic suspensions are absent [19].…”
Section: Manuscript 1 Inmentioning
confidence: 99%