Universal rescaling of flow curves for yield-stress fluids close to jamming

Dinkgreve, M.; Paredes, José; Michels, M.A.J.; Bonn, Daniel

doi:10.1103/physreve.92.012305

Cited by 44 publications

(60 citation statements)

References 85 publications

(221 reference statements)

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“…to henceforth as "mobile" and "rigid" emulsions) [42]. The liquid volume fraction of the shaving foam was 9.2 ± 0.5 %, with a mean bubble radius of about 18 micrometers, in fair agreement with previously reported data on the same brand [43].…”

Section: Methodssupporting

confidence: 67%

Normal stress measurement in foams and emulsions in the presence of slip

Habibi

Dinkgreve

Paredes

et al. 2016

Journal of Non-Newtonian Fluid Mechanics

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Section: Methodssupporting

confidence: 67%

Normal stress measurement in foams and emulsions in the presence of slip

Habibi

Dinkgreve

Paredes

et al. 2016

Journal of Non-Newtonian Fluid Mechanics

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“…As discussed above, flow curves above the critical jamming volume fraction can collapse into one master branch by plotting σ/|∆φ| ∆ vsγ/|∆φ| Γ [4,5]. Consistent with prior work, we find scaling collapse using ∆ ≈ 2.1 and Γ ≈ 3.8, see Figure 2c.…”

Section: Volume Fraction Versus Confining Pressuresupporting

confidence: 88%

Scaling of flow curves: Comparison between experiments and simulations

Dekker

Dinkgreve

Cagny

et al. 2018

Journal of Non-Newtonian Fluid Mechanics

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Yield stress materials form an interesting class of materials that behave like solids at small stresses, but start to flow once a critical stress is exceeded. It has already been reported both in experimental and simulation work that flow curves of different yield stress materials can be scaled with the distance to jamming or with the confining pressure. However, different scaling exponents are found between experiments and simulations. In this paper we identify sources of this discrepancy. We numerically relate the volume fraction with the confining pressure and discuss the similarities and differences between rotational and oscillatory measurements. Whereas simulations are performed in the elastic response regime close to the jamming transition and with very small amplitudes to calculate the scaling exponents, these conditions are hardly possible to achieve experimentally. Measurements are often performed far away from the critical volume fraction and at large amplitudes. We show that these differences are the underlying reason for the different exponents for rescaling flow curves.

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“…Figure 11: Scaled pressure p * (a) and stress ratio µ (b) plotted against the volume fraction, for the proposed constitutive model (solid lines, Eqs. (12) and (16)), and the constitutive model of Chialvo et al [8] (dashed lines, Eqs. (22) and (23)).…”

Section: Comparison With Other Modelsmentioning

confidence: 99%

“…4. Finally, Paredes et al [45] have presented a microscopic two-state theory for yield-stress fluids, elaborated in more detail by Dinkgreve et al [12] , to describe the transition between jammed and unjammed states. Yieldstress fluids are complex fluids composed of dispersions of one material (particles, drops or bubbles) in a liquid (or continuous phase), whose mechanical behavior is characterized by the emergence of a yield stress for volume fractions higher than some critical value (the jamming volume fraction) and Newtonian flow for lower volume fractions, with shear thinning in either case for high shear rates.…”

Section: Berzi and Jenkinsmentioning

confidence: 99%

Merging fluid and solid granular behavior

Vescovi

Luding

2016

Soft Matter

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Simple homogeneous shear flows of frictionless, deformable particles are studied by particle simulations at large shear rates and for differently soft, deformable particles. The particle stiffness sets a time-scale that can be used to scale the physical quantities; thus the dimensionless shear rate, i.e. the inertial number I (inversely proportional to pressure), can alternatively be expressed as inversely proportional to the square root of the particle stiffness. Asymptotic scaling relations for the field variables pressure, shear stress and granular temperature are inferred from simulations in both fluid and solid regimes, corresponding to unjammed and jammed conditions. Then the limit cases are merged to unique constitutive relations that cover also the transition zone in proximity of jamming. By exploiting the diverging behavior of the scaling laws at the jamming density, we arrive at continuous and differentiable phenomenological constitutive relations for the stresses and the granular temperature as functions of the volume fraction, shear rate, particle stiffness and distance from jamming. In contrast to steady shear flows of hard particles the (shear) stress ratio µ does not collapse as a function of the inertial number, indicating the need for an additional control parameter. In the range of particle stiffnesses investigated, in the solid regime, only the pressure is rate independent, whereas the shear stress exhibits a slight shear rateand stiffness-dependency.

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Universal rescaling of flow curves for yield-stress fluids close to jamming

Cited by 44 publications

References 85 publications

Normal stress measurement in foams and emulsions in the presence of slip

Normal stress measurement in foams and emulsions in the presence of slip

Scaling of flow curves: Comparison between experiments and simulations

Merging fluid and solid granular behavior

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