Classical Solvability of the Radial Viscous Fingering Problem in a Hele–Shaw Cell with Surface Tension

In this paper, we review some aspects of viscous fingering in a Hele-Shaw cell that at first sight appear to defy intuition. These include singular effects of surface tension relative to the corresponding zero-surface-tension problem both for the steady and unsteady problem. They also include a disproportionately large influence of small effects like local inhomogeneity of the flow field near the finger tip, or of the leakage term in boundary conditions that incorporate realistic thin-film effects. Through simple explicit model problems, we demonstrate how such properties are not unexpected for a system approaching structural instability or ill-posedness.

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Classical Solvability of the Two-Phase Radial Viscous Fingering Problem in a Hele-Shaw Cell

Mathematical Fluid Dynamics, Present and Future - Springer Proceedings in Mathematics & Statistics ◽

10.1007/978-4-431-56457-7_11 ◽

2016 ◽

pp. 317-348 ◽

Cited By ~ 1

Author(s):

Atusi Tani ◽

Hisasi Tani

Keyword(s):

Viscous Fingering ◽

Two Phase ◽

Classical Solvability ◽

Hele Shaw Cell

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Fractal Characteristics of Viscous Fingering

Fractals ◽

10.1142/s0218348x97000218 ◽

1997 ◽

Vol 05 (02) ◽

pp. 221-227 ◽

Cited By ~ 2

Author(s):

Songyue Tang ◽

Zhonglei Wei

Keyword(s):

Surface Tension ◽

Monte Carlo ◽

Stochastic Simulation ◽

Viscosity Ratio ◽

Fractal Dimensions ◽

Viscous Fingering ◽

Experimental Results ◽

Fractal Characteristics ◽

Hele Shaw Cell ◽

Good Agreement

Viscous fingering is investigated by experiment in a 2-dimensional radial Hele-Shaw cell and Monte Carlo stochastic simulation. Experimental results show that viscosity ratio between the driving and driven fluids determines whether or not viscous fingerings occur and that surface tension makes the viscous fingering patterns "fatter". Simulation patterns are in good agreement with experimental ones. The fractal dimensions of the viscous fingering patterns by both experiments and simulations are about Df=1.2-1.6.

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Viscous-fingering mechanisms under a peeling elastic sheet

Journal of Fluid Mechanics ◽

10.1017/jfm.2019.59 ◽

2019 ◽

Vol 864 ◽

pp. 1177-1207

Author(s):

Gunnar G. Peng ◽

John R. Lister

Keyword(s):

Surface Tension ◽

Stability Analysis ◽

Cell Walls ◽

Viscous Fingering ◽

Base Flow ◽

Fingering Instability ◽

Linear Perturbations ◽

The Stability ◽

Rigid Walls ◽

Hele Shaw Cell

We study the mechanisms affecting the viscous-fingering instability in an elastic-walled Hele-Shaw cell by considering the stability of steady states of unidirectional peeling-by-pulling and peeling-by-bending. We demonstrate that the elasticity of the wall influences the steady base state but has a negligible direct effect on the behaviour of linear perturbations, which thus behave like in the ‘printer’s instability’ with rigid walls. Moreover, the geometry of the cell can be very well approximated as a triangular wedge in the stability analysis. We identify four distinct mechanisms – surface tension acting on the horizontal and the vertical interfacial curvatures, kinematic compression in the longitudinal base flow, and the films deposited on the cell walls – that each contribute to stabilizing the system. The vertical curvature is the dominant stabilizing mechanism for small capillary numbers, but all four mechanisms have a significant effect in a large region of parameter space.

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Global instability of viscous fingering in a Hele–Shaw cell: formation of oscillatory fingers

European Journal of Applied Mathematics ◽

10.1017/s0956792500000437 ◽

1991 ◽

Vol 2 (2) ◽

pp. 105-132 ◽

Cited By ~ 17

Author(s):

Jian-Jun Xu

Keyword(s):

Surface Tension ◽

Travelling Waves ◽

Cell Formation ◽

Stable State ◽

Viscous Fingering ◽

Instability Mechanism ◽

Global Instability ◽

Trapped Wave ◽

Global Modes ◽

Hele Shaw Cell

This work deals with the global instability mechanism of viscous fingering in a Hele–Shaw cell with the inclusion of surface tension. We investigate the interaction and propagation of travelling waves in the system, and obtain two discrete sets of global wave modes: symmetrical modes and anti-symmetrical modes. We call the instability mechanism determined by these global modes the global trapped wave (GTW) instability. A unique global, neutrally stable state of the system is found; it explains the formation of the narrow, oscillatory fingers discovered by Couder el al. (1986) and by Kopf-Sill & Homsy (1987).

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