Miscible displacement in a Hele-Shaw cell at high rates

Lajeunesse, É.; Martin, James E.; Rakotomalala, N.; Salin, D.; Yortsos, Y.C.

doi:10.1017/s0022112099006357

Cited by 146 publications

(124 citation statements)

References 21 publications

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“…Their nonlinear simulations of the Stokes equations predict that increasing the unstable density stratification and decreasing diffusion increase the front velocity. The flow fields obtained by these simulations are qualitatively similar to those observed in the experiment of Petitjeans & Maxworthy (1996) in capillary tubes and in the theoretical predictions of Lajeunesse et al (1999) for Hele-Shaw cells. The study of Petitjeans & Maxworthy (1996) discussed the formation and propagation of a single finger for a miscible fluid in a capillary tube.…”

Section: Introductionsupporting

confidence: 82%

“…Experimental studies in miscible core-annular flows (Taylor 1961;Cox 1962;Chen & Meiburg 1996;Petitjeans & Maxworthy 1996;Kuang, Maxworthy & Petitjeans 2003) have focused on analysing the thickness of the more viscous fluid layer left on the pipe walls and the speed of the propagating 'finger' tip. The development of different instability patterns, like axisymmetric 'corkscrew' patterns, in miscible flows has also been investigated (Lajeunesse et al 1997(Lajeunesse et al , 1999Scoffoni, Lajeunesse & Homsy 2001;Cao et al 2003;Gabard & Hulin 2003). Axisymmetric 'pearl' and 'mushroom' patterns were observed in neutrally buoyant core-annular horizontal pipe flows at high Schmidt number and Reynolds number in the range 2 < Re < 60 (d 'Olce et al 2008).…”

Section: Introductionmentioning

confidence: 99%

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Double diffusive effects on pressure-driven miscible displacement flows in a channel

2012

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The pressure-driven miscible displacement of a less viscous fluid by a more viscous one in a horizontal channel is studied. This is a classically stable system if the more viscous solution is the displacing one. However, we show by numerical simulations based on the finite-volume approach that, in this system, double diffusive effects can be destabilizing. Such effects can appear if the fluid consists of a solvent containing two solutes both influencing the viscosity of the solution and diffusing at different rates. The continuity and Navier–Stokes equations coupled to two convection–diffusion equations for the evolution of the solute concentrations are solved. The viscosity is assumed to depend on the concentrations of both solutes, while density contrast is neglected. The results demonstrate the development of various instability patterns of the miscible ‘interface’ separating the fluids provided the two solutes diffuse at different rates. The intensity of the instability increases when increasing the diffusivity ratio between the faster-diffusing and the slower-diffusing solutes. This brings about fluid mixing and accelerates the displacement of the fluid originally filling the channel. The effects of varying dimensionless parameters, such as the Reynolds number and Schmidt number, on the development of the ‘interfacial’ instability pattern are also studied. The double diffusive instability appears after the moment when the invading fluid penetrates inside the channel. This is attributed to the presence of inertia in the problem.

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Section: Introductionsupporting

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Double diffusive effects on pressure-driven miscible displacement flows in a channel

2012

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“…Generally poor agreement is observed between the Stokes results and corresponding findings for Darcy flows [4]. [5] extend this investigation to variable density displacements in vertical Hele-Shaw cells and find excellent agreement with the experimental data of [6] regarding the most amplified wavelength. These results establish Stokes based direct simulations and accompanying linear stability analyses as powerful tools for comparing Hele-Shaw displacements with their Darcy based counterparts.…”

Section: Introductionmentioning

confidence: 49%

Miscible displacements in Hele–Shaw cells: Nonmonotonic viscosity profiles

Schafroth

Goyal

Meiburg

2007

European Journal of Mechanics - B/Fluids

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The influence of nonmonotonic viscosity-concentration relationships on viscous fingering of neutrally buoyant, miscible fluids in a Hele-Shaw cell has been investigated. In a first step, quasisteady base states are obtained by means of nonlinear Stokes simulations. The properties of these base states are analyzed as a function of the Péclet number, the viscosity ratio, and the profile parameters. Subsequently, the stability of these base states is investigated by means of a linear stability analysis. Overall, the nonmonotonicity of the viscosity-concentration relationship is seen to have a much smaller influence on Hele-Shaw displacements than on corresponding Darcy flows. The reason for this difference lies in the nature of the respective base states. For Darcy flows, the base state is characterized by constant velocity and a diffusively decaying concentration (and hence viscosity) profile. This base viscosity profile is strongly affected by the nonmonotonicity. On the other hand, for Hele-Shaw displacements the quasisteady base states are convectively dominated and characterized by sharp fronts, so that their shape depends only weakly on the details of the viscosity-concentration relationship. Hence, for Hele-Shaw displacements both the eigenfunctions and the associated growth rates are quite similar for monotonic and nonmonotonic profiles, in contrast to the findings by [O. Manickam, G.M. Homsy, Stability of miscible displacements in porous media with nonmonotonic viscosity profiles, Phys. Fluids A 5 (1993Fluids A 5 ( ) 1356Fluids A 5 ( -1367 for Darcy flows.

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“…We investigate the growth of patterns formed in the small-wavelength limit using pairs of miscible fluids, where the interfacial tension s is negligible. For large enough Peclet numbers, where advection dominates over diffusion, the inter-diffusion of the fluids is negligible so that the fluids remain separated by a well-defined interface [20][21][22] . This is the situation we investigate here.…”

Section: Resultsmentioning

confidence: 99%

Fingering versus stability in the limit of zero interfacial tension

2014

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The invasion of one fluid into another of higher viscosity in a quasi-two dimensional geometry typically produces complex fingering patterns. Because interfacial tension suppresses short-wavelength fluctuations, its elimination by using pairs of miscible fluids would suggest an instability producing highly ramified singular structures. Previous studies focused on wavelength selection at the instability onset and overlooked the striking features appearing more globally. Here we investigate the non-linear growth that occurs after the instability has been fully established. We find a rich variety of patterns that are characterized by the viscosity ratio between the inner and the outer fluid, Z in /Z out , as distinct from the mostunstable wavelength, which determines the onset of the instability. As Z in /Z out increases, a regime dominated by long highly-branched fractal fingers gives way to one dominated by blunt stable structures characteristic of proportionate growth. Simultaneously, a central region of complete outer-fluid displacement grows until it encompasses the entire pattern at Z in /Z out E0.3.

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Miscible displacement in a Hele-Shaw cell at high rates

Cited by 146 publications

References 21 publications

Double diffusive effects on pressure-driven miscible displacement flows in a channel

Double diffusive effects on pressure-driven miscible displacement flows in a channel

Miscible displacements in Hele–Shaw cells: Nonmonotonic viscosity profiles

Fingering versus stability in the limit of zero interfacial tension

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