Modeling Immiscible Two‐Phase Flow in Rough Fractures From Capillary to Viscous Fingering

Yang, Zhibing; Méheust, Yves; Neuweiler, Insa; Hu, Ran; Niemi, Auli; Chen, Yi‐Feng

doi:10.1029/2018wr024045

Cited by 39 publications

(22 citation statements)

References 67 publications

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“…To overcome this shortcoming, microscopic approaches such as Stokes' solution for flow in single pores with a specified geometry or lattice Boltzmann methods (LBM) have been investigated to reproduce experiments (Aursjø et al, 2010;Fiorentino et al, 2017;Misztal et al, 2015). Similarly, pore-scale network models have been developed to study a wide range of displacement processes, including drainage and imbibition (Aker et al, 1998;Joekar Niasar et al, 2009;Kallel et al, 2017;Nordhaug et al, 2003;Nsir et al, 2012Nsir et al, , 2018Sheng & Thompson, 2013;Singh & Mohanty, 2003;Tørå et al, 2012;Yang et al, 2019). Ewing and Berkowitz (1998) developed a generalized growth model based on invasion percolation to simulate immiscible displacement in saturated porous media.…”

Section: Introductionmentioning

confidence: 99%

Gravitational and Finite‐Size Effects On Pressure Saturation Curves During Drainage

Ayaz

Toussaint

Schäfer

et al. 2020

Water Resources Research

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We experimentally and numerically study the influence of gravity and finite-size effects on the pressure-saturation relationship in a given porous medium during slow drainage. The effect of gravity is systematically varied by tilting the system relative to the horizontal configuration. The use of a quasi two-dimensional porous media allows for direct spatial monitoring of the saturation. Exploiting the fractal nature of the invasion structure, we obtain a relationship between the final saturation and the Bond number S F nw = Bo 0.097 using percolation theory. Moreover, the saturation, pressure, and Bond number are functionally related, allowing for pressure-saturation curves to collapse onto a single master curve, parameterized by the representative elementary volume size and by the Bond and capillary numbers. This allows to upscale the pressure-saturation curves measured in a laboratory to large representative elementary volumes used in reservoir simulations. The large-scale behavior of these curves follows a simple relationship, depending on Bond and capillary numbers, and on the flow direction. The size distribution of trapped defending fluid clusters is also shown to contain information on past fluid flow and can be used as a marker of past flow speed and direction.

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Section: Introductionmentioning

confidence: 99%

Gravitational and Finite‐Size Effects On Pressure Saturation Curves During Drainage

Ayaz

Toussaint

Schäfer

et al. 2020

Water Resources Research

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“…Immiscible fluid displacement, where surface tension between the two fluids results in so-called capillary forces acting at the fluid-fluid interface, has been studied for Newtonian fluids in both linear (Bonn et al, 1995;Chevalier et al, 2006;Miranda & Widom, 1998;Saffman & Taylor, 1958) and radial (J. Den Chen, 1989;Dias et al, 2012;Miranda & Widom, 1998;Thomé et al, 1989;White & Ward, 2014;Yang et al, 2019) Hele-Shaw cells. Miscible Newtonian fluids, where mixing between the injected and displaced fluids takes place during the displacement, gives rise to more irregular fingering patterns than what is observed for immiscible fluids (J.…”

Section: Introductionmentioning

confidence: 99%

Mixing and finger morphologies in miscible non-Newtonian solution displacement

et al. 2020

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Unexpected interface complexities were found resulting from the miscible displacement of saltwater by a miscible shear-thinning solution (xanthan gum) in a radial Hele-Shaw cell, for both convergent and divergent flow. Such complex patterns have not been described before for either Newtonian or non-Newtonian solutions. A more viscous solution was injected into the cell to displace a less viscous solution (divergent flow) then withdrawn at the injection site (convergent flow). A variegated mixing fringe between the solutions developed during the injection phase, against the stabilizing viscous effects, which would tend to promote a stable piston-like displacement. This interface geometry is markedly different from what is seen in displacement experiments performed with glycerol under otherwise similar viscosity contrast and flow conditions. The concentration field heterogeneity resulting from the presence of the fringe, quantified using a spatial autocorrelation measure, is mostly controlled by the applied shear rate, or equivalently, by the ratio of the volumetric flow rate to the flow cell's aperture. It is significantly correlated to the radial width of the mixing zone. In addition to producing a large volume of blended solution during the injection phase, the mixing fringe impacted the development of viscous fingers (VFs) during the withdrawal phase. Such VFs are expected due to the viscosity ratio, but the initial roughness of the interface from which they develop, and, hence, their later dynamics, are controlled by the geometry of the mixing fringe at the end of the injection. We characterize the dynamics as a function of the imposed flow rate and cell thickness. The observed complexities of miscible displacement involving shear-thinning solutions have implications for subsurface engineering applications such as oil recovery and groundwater remediation.

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“…The roughness induces the aperture variability between the two rock surfaces (AlQuaimi & Rossen, 2017;Brown, 1987), determining the invasion path (Lee et al, 2010;Neuweiler et al, 2004), and controls the displacement patterns and phase distribution (Babadagli et al, 2015;Karpyn et al, 2007). A number of experimental (Chen et al, 2017; and numerical studies (Chen, Guo, et al, 2018;Yang et al, 2019) confirm that the main mechanism controlling the displacement patterns in rough fractures is similar to that in porous media (Toussaint et al, 2012), and similar empirical phase diagrams of displacement patterns have been proposed as a function of capillary number Ca and viscosity ratio M. However, given the significant differences in flow geometry for rock fractures and porous materials, the phase diagram originally established for porous media may not be applicable to flow in rough fractures (Babadagli et al, 2015;. It has been discovered that the roughness of rock surfaces can induce localized flow channels even when a more viscous fluid displaces a less viscous one ), which has not been observed in experiments of Hele-Shaw type or in porous media.…”

Section: Introductionmentioning

confidence: 99%

Roughness Control on Multiphase Flow in Rock Fractures

Zhou

et al. 2019

Geophysical Research Letters

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The roughness of rock fractures induces irregular flow passages and significantly affects the displacement front. Previous studies focus on displacement instabilities in porous media, but how roughness controls displacement patterns in rock fractures remains unclear. Here, we derive a theoretical model that describes the two transitions of drainage displacement patterns from capillary fingering to the crossover to viscous fingering as functions of roughness. The phase diagram predicted by this model exhibits excellent agreement with our experimental results, showing that increasing roughness index λb destabilizes displacement fronts. We further find that in capillary fingering regime the percentage of dissipated energy to the total external work increases from 39% to 61% as λb increases from 0.082 to 0.245. Our work elucidates the mechanism of roughness control on multiphase flow in fractures and provides a basis for developing a rigorous upscaling methodology that relates Darcy‐scale flow behavior to the local fluid displacements via energy dissipation.

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Modeling Immiscible Two‐Phase Flow in Rough Fractures From Capillary to Viscous Fingering

Cited by 39 publications

References 67 publications

Gravitational and Finite‐Size Effects On Pressure Saturation Curves During Drainage

Gravitational and Finite‐Size Effects On Pressure Saturation Curves During Drainage

Mixing and finger morphologies in miscible non-Newtonian solution displacement

Roughness Control on Multiphase Flow in Rock Fractures

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