On the macroscopic modelling of dilute emulsions under flow

Mwasame, Paul M.; Wagner, Norman J.; Beris, Antony N.

doi:10.1017/jfm.2017.578

Cited by 19 publications

(37 citation statements)

References 65 publications

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“…Only in the cases where a 2 = 1 do the viscoelastic constitutive relations exhibit a well-defined elastic limit, in the sense that their behaviours converge to that of an elastic solid in the limit of λ → ∞. The very same conclusions were reached in the context of emulsions, whose drops deform into ellipsoids—in that case the eigenvalues of A represent the square of the semi-axes of the deformed droplets [59,60]. Any other time derivative, which implies non-affine motion, does not correspond to any limit of the theory of elasticity.…”

Section: The Limit λ → ∞: Do All Viscoelastic Models Converge To Elastic Solids?mentioning

confidence: 84%

“…Any isotropic contribution to the stress can be written as part of the pressure p. The non-Newtonian contribution σ p originates from the presence of the microstructure inside the fluid. Though we will refer to σ p as the 'polymeric stress', having in mind dilute polymer suspensions, the concept equally applies to emulsions whose microstructure is described by droplet deformations [59,60]. The stress σ p is governed by a separate evolution equation, the constitutive equation, which encodes the non-Newtonian properties of the fluid.…”

Section: Classical Continuum Theorymentioning

confidence: 99%

“…In § 5 c, we supply a list of various models. Apart from the question of frame invariance, models have to be consistent with the requirements of thermodynamics [ 6 , 7 , 59 , 60 , 63 ].…”

Section: Classical Continuum Theorymentioning

confidence: 99%

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The relationship between viscoelasticity and elasticity

et al. 2020

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Soft materials that are subjected to large deformations exhibit an extremely rich phenomenology, with properties lying in between those of simple fluids and those of elastic solids. In the continuum description of these systems, one typically follows either the route of solid mechanics (Lagrangian description) or the route of fluid mechanics (Eulerian description). The purpose of this review is to highlight the relationship between the theories of viscoelasticity and of elasticity, and to leverage this connection in contemporary soft matter problems. We review the principles governing models for viscoelastic liquids, for example solutions of flexible polymers. Such materials are characterized by a relaxation time λ , over which stresses relax. We recall the kinematics and elastic response of large deformations, and show which polymer models do (and which do not) correspond to a nonlinear elastic solid in the limit λ → ∞. With this insight, we split the work done by elastic stresses into reversible and dissipative parts, and establish the general form of the conservation law for the total energy. The elastic correspondence can offer an insightful tool for a broad class of problems; as an illustration, we show how the presence or absence of an elastic limit determines the fate of an elastic thread during capillary instability.

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Section: The Limit λ → ∞: Do All Viscoelastic Models Converge To Elastic Solids?mentioning

confidence: 84%

Section: Classical Continuum Theorymentioning

confidence: 99%

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The relationship between viscoelasticity and elasticity

et al. 2020

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“…In this work, we will employ non-equilibrium thermodynamics (NET) to develop a sophisticated mathematical model addressing the rheological behavior of nanoblood. To accomplish this, we will develop the model using the generalized bracket formalism (Beris and Edwards 1994 ) of NET (Beris and Edwards 1994 ; Grmela and Öttinger 1997 ; Öttinger and Grmela 1997 ; Edwards et al 2003 ; Öttinger 2005 ), by means of which several microstructured systems have been addressed up to date, such as, but not limited to, immiscible complex fluids (Edwards and Dressler 2003 ; Dressler and Edwards 2004 ; Dressler et al 2008 ; Grmela et al 2014 ; Mwasame et al 2017 ), polymer melts and solutions (Beris and Edwards 1994 ; Grmela and Öttinger 1997 ; Öttinger and Grmela 1997 ; Öttinger 2005 ; Stephanou et al 2009 , 2016 , 2020b ), polymer nanocomposites (Rajabian et al 2005 ; Eslami et al 2010 ; Stephanou et al 2014 ; Stephanou 2015 ), micellar systems (Germann et al 2013 ; Stephanou et al 2020a ), blood (Tsimouri et al 2018 ; Stephanou 2020 ; Stephanou and Tsimouri 2020 ), drilling fluids (Stephanou 2018 ), and thixotropic fluids (Stephanou and Georgiou 2018 ). The use of a NET formalism has the compelling advantage, over other approaches, that the constitutive model as a whole is guaranteed consistency with the laws of thermodynamics (as extended for beyond equilibrium systems).…”

Section: Introductionmentioning

confidence: 99%

Elucidating the rheological implications of adding particles in blood

Stephanou

2021

Rheol Acta

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Graphical abstract In the past few decades, nanotechnology has been employed to provide breakthroughs in the diagnosis and treatment of several diseases using drug-carrying particles (DCPs). In such an endeavor, the optimal design of DCPs is paramount, which necessitates the use of an accurate and trustworthy constitutive model in computational fluid dynamics (CFD) simulators. We herein introduce a continuum model for elaborating on the rheological implications of adding particles in blood. The model is developed using non-equilibrium thermodynamics to guarantee thermodynamic admissibility. Red blood cells are modeled as deformed droplets with a constant volume that are able to aggregate, whereas particles are considered rigid spheroids. The model predictions are compared favorably against rheological data for both spherical and non-spherical particles immersed in non-aggregating blood. It is expected that the use of this model will allow for the testing of DCPs in virtual patients and for their tailor-design in treating various diseases. Supplementary Information The online version contains supplementary material available at 10.1007/s00397-021-01289-x.

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“…The non-Newtonian contribution σ p originates from the stretching of the microstructure inside the fluid. Though we will refer to σ p as the "polymeric stress", having in mind dilute polymer suspensions, the concept equally applies to emulsions whose microstructure is described by droplet deformations [20,21]. The non-Newtonian contribution σ p is governed by a separate evolution equation, describing the state of the component governed by a long time scale λ, for example a polymer.…”

Section: Classical Continuum Theory a Viscoelastic Fluidsmentioning

confidence: 99%

The relationship between viscoelasticity and elasticity

Snoeijer,

Pandey,

Herrada

et al. 2019

Preprint

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We consider models for elastic liquids, such as solutions of flexible polymers. They introduce a relaxation time λ into the system, over which stresses relax. We study the kinematics of the problem, and clarify the relationship between Lagrangian and Eulerian descriptions, thereby showing which polymer models correspond to a nonlinear elastic deformation in the limit λ → ∞. This allows us to split the change in elastic energy into reversible and dissipative parts, and thus to write an equation for the total energy, the sum of kinetic and elastic energies. As an illustration, we show how the presence or absence of an elastic limit determines the fate of an elastic thread during capillary instability, using novel numerical schemes based on our insights into the flow kinematics.

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On the macroscopic modelling of dilute emulsions under flow

Cited by 19 publications

References 65 publications

The relationship between viscoelasticity and elasticity

The relationship between viscoelasticity and elasticity

Elucidating the rheological implications of adding particles in blood

The relationship between viscoelasticity and elasticity

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