Evidence for a universal saturation profile for radial viscous fingers

Beeson-Jones, Tim H.; Woods, Andrew W.

doi:10.1038/s41598-019-43728-z

Cited by 6 publications

(3 citation statements)

References 13 publications

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“…When the intermediate flow rate Q = 0.1 μL/min, the slope k c of linear fitting line of the S inv −x inv curve was the largest with k c = 0.47, corresponding to an uniform invasion front in Figure 8b. As the flow rate decreased to Q = 0.025 μL/min, water invaded into the pore structure saturated with oil at the beginning of the invasion displaying a compact interface as a result of the capillary dispersion effect 60,61 (Figure 8a 1 ), which was similar to the results reported by Chen et al 52 in rough fractures. After the preferential flow paths developed, the invasion front became branched (Figure 8a 2 −a 5 ) leading to much oil being trapped.…”

Section: Quantitative Analysis Of Displacement Patternssupporting

confidence: 87%

Effects of Capillary and Viscous Forces on Two-Phase Fluid Displacement in the Microfluidic Model

Chen,

Liu,

Wang

et al. 2023

Energy Fuels

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Immiscible fluid−fluid displacement in porous media is an important phenomenon that impacts the field of underground energy and environmental engineering, such as enhanced oil/gas recovery, geological CO 2 sequestration, and transport and remediation of groundwater pollutants. In enhanced oil recovery, the occurrence of the fingering instability of the two-phase flow interface causes a significant reduction in the oil recovery factor for waterflooding. In geological CO 2 sequestration, the efficiency of CO 2 capillary/residual trapping is limited by the noncompact displacement pattern, presenting only part of brine displaced by scCO 2 . Although extensive studies have investigated viscous and capillary fingering in porous media, how viscous and capillary forces affect the crossover is not well understood. Quantifying and characterizing the transition of immiscible fluid−fluid displacement patterns are therefore important. In this article, comprehensive investigation of capillary number and viscosity ratio effects on displacement patterns and efficiency was established by a series of displacement microfluidic experiments in a homogeneous pore network. Three pairs of nonwetting−wetting immiscible fluids with viscosity ratios M ranging from 1/1000 to 1000 were used to perform the displacement experiments. The drainage experiments of water displacing silicone oil were conducted under five flow rate conditions with capillary number log 10 Ca ranging from −7.19 to −3.45, while the imbibition experiments of silicone oil displacing water displayed at four flow rates with log 10 Ca varying from −7.25 to −2.52. The relationship between displacement efficiency S inv and fractal dimension D f as a function of M and Ca was established to quantitatively determine the transition of displacement patterns (capillary fingering, viscous fingering, stable displacement, and ordered dendritic). The results indicated that D f increased with S inv under unfavorable conditions (M < 1) and decreased as S inv for M > 1, and lower invading fluid saturations were observed in the crossover zone between capillary fingering and viscous fingering for M = 1/20 and 1/200. Based on the pore-scale analysis of pore-filling events and microscopic observation, the theoretical model of the transitions for invasion modes were proposed to determine the critical capillary corresponding to viscosity ratio and contact angle. This study extends the classic log 10 M−log 10 Ca phase diagram and quantifies the dynamic effects of capillary force and viscous force on the immiscible fluid−fluid displacement process.

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Section: Quantitative Analysis Of Displacement Patternssupporting

confidence: 87%

Effects of Capillary and Viscous Forces on Two-Phase Fluid Displacement in the Microfluidic Model

Chen,

Liu,

Wang

et al. 2023

Energy Fuels

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“…In addition, the distance between the finger roots and the center position (injection hole) remains the same after the critical time ( t c ), which is defined as the critical instability radius ( r c ) in this work. According to the previous study ( Beeson-Jones and Woods, 2019 ), when the initial and boundary conditions remain unchanged, this radius ( r c ) keeps constant. Therefore, we can judge the suppression/promotion of EVF by analysing this distance and its evolutional details.…”

Section: Resultsmentioning

confidence: 76%

Active control of electro-visco-fingering in Hele-Shaw cells using Maxwell stress

Li¹,

Huang²,

Zhao³

2022

iScience

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“…The flower-shaped crystallization pattern resembles a fingering instability ,− that occurs due to Saffman–Taylor instabilities. Saffman–Taylor viscous fingering is observed when a fluid with lower viscosity is injected into one with a higher viscosity leading to a relative velocity difference between the two fluids.…”

Section: Resultsmentioning

confidence: 99%

Patterns during Evaporative Crystallization of a Saline Droplet

Kumar

Dash

2022

Langmuir

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In the present work, we investigate the influence of substrate wettability and crystal morphology on the evaporative crystallization of saline droplets. On a superhydrophilic substrate, the evaporative crystals formed during the drying of a saline droplet of aqueous potassium nitrate are observed to be long and needle-shaped, oriented along the substrate. The crystal deposits form a flower-shaped pattern when the initial contact angle of the droplet increases to ∼72°. The orientation of the crystals along the triple contact line of the droplet controls the self-amplifying creeping growth of the salt crystals that eventually determines the overall evaporative patterns. The crystals change from being needle-shaped to globular salt deposits as the volume of liquid available for crystallization reduces. We demonstrate that the arrangement of the crystal with respect to the substrate and the droplet–air interface governs the rate of evaporation, growth, and morphology of the crystals.

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Evidence for a universal saturation profile for radial viscous fingers

Cited by 6 publications

References 13 publications

Effects of Capillary and Viscous Forces on Two-Phase Fluid Displacement in the Microfluidic Model

Effects of Capillary and Viscous Forces on Two-Phase Fluid Displacement in the Microfluidic Model

Active control of electro-visco-fingering in Hele-Shaw cells using Maxwell stress

Patterns during Evaporative Crystallization of a Saline Droplet

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