A nonequilibrium thermodynamics perspective of thixotropy

Tsimouri

2020

Soft Matter

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Section: Introductionmentioning

confidence: 99%

A constitutive hemorheological model addressing the deformability of red blood cells in Ringer solutions

Tsimouri

2020

Soft Matter

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“…We have recently proposed (Stephanou 2020 ) that to accomplish this we need to employ one additional scalar structural variable, , to properly characterize the network formed by RBCs. When the network is fully formed, then =1, while in a completely broken state, i.e., when only single RBCs remain, it vanishes (Mewis and Wagner 2009 ; Stephanou and Georgiou 2018 ). Next, we consider particles as rigid spheroids; to describe the average particle orientation, we consider the orientation tensor defined (Stephanou et al 2014 ; Stephanou 2015 ) as where is the particle’s director vector and is the orientational distribution function for the vector at position and time .…”

Section: Model Derivationmentioning

confidence: 99%

“…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

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.

“…To accomplish this, we will develop the model using the Generalized bracket formalism 28 of NET, [28][29][30][31] by means of which several microstructured systems have been addressed, such as polymer melts and solutions, [28][29][30]32,33 polymer nanocomposites, 34,35 micellar systems, 36,37 blood, [38][39][40] drilling fluids, 41 and thixotropic fluids. 42 Thus, we guarantee that the model derived will be consistent with the law of thermodynamics as extended for beyond equilibrium systems. Also, we guarantee that the coupling between the various variables is accomplished self-consistently.…”

Section: Introductionmentioning

confidence: 71%

On the consistent modeling of shear-thickening polymer solutions

2021

Physics of Fluids

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During the past few decades, the interest in understanding the peculiar rheological behavior of shear-thickening fluids has increased due to their potential use in various commercial applications. In such an endeavor, the optimal design of these fluids is essential, which necessitates our in-depth understanding of their properties from a modeling perspective. We herein introduce a continuum model to predict the rheological behavior of shear-thickening polymer solutions using non-equilibrium thermodynamics that guarantees, by construction, consistency with the laws of thermodynamics as extended to handle non-equilibrium systems. This is made possible by using a scalar structural variable that characterizes the formation of the shear-induced structure at sufficiently high shear rates, and a conformation tensor that characterizes the deformation of the polymer segments. The model predicts the exhibition of a shear-thickening behavior for all steady shear flow material functions (shear viscosity and normal stress coefficients), which is then followed by a shear-thinning behavior if finite extensibility or anisotropic effects are considered. We further document that these model predictions are in line with available shear viscosity rheological data for shear-thickening polymer solutions.