Deformation and breakup of viscoelastic droplets in confined shear flow

Gupta, A.; Sbragaglia, Mauro

doi:10.1103/physreve.90.023305

Cited by 50 publications

(61 citation statements)

References 74 publications

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“…Numerical simulations [20] indicate that (for fixed flow conditions) the effects of viscoelasticity are more pronounced in the case of Newtonian droplets in a viscoelastic carrier liquid than in the complementary case of viscoelastic droplets in a Newtonian medium. This difference is quantitatively attributed to the fact that the flow driving the break-up process upstream of the emerging thread can be sensibly perturbed by a viscoelastic behavior of the continuous phase, obtained for example by adding polymers [20].…”

Section: Introductionmentioning

confidence: 95%

“…This difference is quantitatively attributed to the fact that the flow driving the break-up process upstream of the emerging thread can be sensibly perturbed by a viscoelastic behavior of the continuous phase, obtained for example by adding polymers [20]. We thus decided to investigate the viscoelastic effects of the continuous phase on the formation of (Newtonian) droplets.…”

Section: Introductionmentioning

confidence: 99%

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Generation of Oil Droplets in a Non-Newtonian Liquid Using a Microfluidic T-Junction

et al. 2015

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Abstract:We have compared the formation of oil drops in Newtonian and non-Newtonian fluids in a T-junction microfluidic device. As Newtonian fluids, we used aqueous solutions of glycerol, while as non-Newtonian fluids we prepared aqueous solutions of xanthan, a stiff rod-like polysaccharide, which exhibit strong shear-thinning effects. In the squeezing regime, the formation of oil droplets in glycerol solutions is found to scale with the ratio of the dispersed flow rate to the continuous one and with the capillary number associated to the continuous phase. Switching to xanthan solutions does not seem to significantly alter the droplet formation process. Any quantitative difference with respect to the Newtonian liquid can be accounted for by a suitable choice of the capillary number, corresponding to an effective xanthan viscosity that depends on the flow rates. We have deduced ample variations in the viscosity, on the order of 10 and more, during normal operation conditions of the T-junction. This allowed estimating the actual shear rates experienced by the xanthan solutions, which go from tens to hundreds of s´1.

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Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Generation of Oil Droplets in a Non-Newtonian Liquid Using a Microfluidic T-Junction

et al. 2015

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“…The parameter L 2 is actually related to the extensional viscosity of the polymers [26,30]. In the spirit of the work that we recently developed for characterizing droplet deformation and break-up in confined shear flow [25], it would be of extreme interest to study the impact of a change in the finite extensibility parameter L 2 for the geometries studied in this paper [13,16]. Finally, we wish to underscore the role played by numerical simulations: in real experiments all the various processes (hydrodynamic forces, viscoelastic effects, confinement effects) occur at the same time and it is next to impossible to separately quantify their relative importance.…”

Section: Discussionmentioning

confidence: 99%

Viscoelastic multicomponent fluids in confined flow-focusing devices

Gupta

Sbragaglia

Foard

et al. 2015

AIP Conference Proceedings

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Abstract. The effects of elasticity on the break-up of liquid threads in microfluidic cross-junctions is investigated using numerical simulations based on the "lattice Boltzmann models" (LBM). Working at small Capillary numbers, we investigate the effects of non-Newtonian phases in the transition from droplet formation at the cross-junction (DCJ) and droplet formation downstream of the cross-junction (DC) (Liu & Zhang, Phys. Fluids. 23, 082101 (2011)). Viscoelasticity is found to influence the break-up point of the threads, which moves closer to the cross-junction and stabilizes. This is attributed to an increase of the polymer feedback stress forming in the corner flows, where the side channels of the device meet the main channel.

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“…LBM is instrumental to solve the diffuse-interface hydrodynamic equations of a binary mixture of two components [36,37,38,39,40,41]: the resulting physical domain can be partitioned into different subdomains, each occupied by a "pure" fluid, with the interface between the two fluids described as a thin layer where the fluid properties change smoothly. The FENE-P constitutive equations are solved with a finite difference scheme which is coupled with the solvent LBM as described in [42,43]. The numerical approach has been extensively validated in our previous works [42,43], where we have provided evidence that the model is able to capture quantitatively rheological properties of dilute suspensions as well as deformation and orientation of single viscoelastic droplets in confined shear flows.…”

Section: Theoretical Modelmentioning

confidence: 99%

“…The FENE-P constitutive equations are solved with a finite difference scheme which is coupled with the solvent LBM as described in [42,43]. The numerical approach has been extensively validated in our previous works [42,43], where we have provided evidence that the model is able to capture quantitatively rheological properties of dilute suspensions as well as deformation and orientation of single viscoelastic droplets in confined shear flows. The main essential features of the model are recalled in Appendix A.…”

Section: Theoretical Modelmentioning

confidence: 99%

Effects of viscoelasticity on droplet dynamics and break-up in microfluidic T-Junctions: a lattice Boltzmann study

Gupta

Sbragaglia

2016

Eur. Phys. J. E

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Abstract. The effects of viscoelasticity on the dynamics and break-up of fluid threads in microfluidic T-junctions are investigated using numerical simulations of dilute polymer solutions at changing the Capillary number (Ca), i.e. at changing the balance between the viscous forces and the surface tension at the interface, up to Ca ≈ 3 × 10 −2 . A NavierStokes (NS) description of the solvent based on the lattice Boltzmann models (LBM) is here coupled to constitutive equations for finite extensible non-linear elastic dumbbells with the closure proposed by Peterlin (FENE-P model). We present the results of three-dimensional simulations in a range of Ca which is broad enough to characterize all the three characteristic mechanisms of breakup in the confined T-junction, i.e. squeezing, dripping and jetting regimes. The various model parameters of the FENE-P constitutive equations, including the polymer relaxation time τ P and the finite extensibility parameter L 2 , are changed to provide quantitative details on how the dynamics and break-up properties are affected by viscoelasticity. We will analyze cases with Droplet Viscoelasticity (DV), where viscoelastic properties are confined in the dispersed (d) phase, as well as cases with Matrix Viscoelasticity (MV), where viscoelastic properties are confined in the continuous (c) phase. Moderate flow-rate ratios Q ≈ O(1) of the two phases are considered in the present study. Overall, we find that the effects are more pronounced in the case with MV, as the flow driving the break-up process upstream of the emerging thread can be sensibly perturbed by the polymer stresses.

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Deformation and breakup of viscoelastic droplets in confined shear flow

Cited by 50 publications

References 74 publications

Generation of Oil Droplets in a Non-Newtonian Liquid Using a Microfluidic T-Junction

Generation of Oil Droplets in a Non-Newtonian Liquid Using a Microfluidic T-Junction

Viscoelastic multicomponent fluids in confined flow-focusing devices

Effects of viscoelasticity on droplet dynamics and break-up in microfluidic T-Junctions: a lattice Boltzmann study

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