2012
DOI: 10.1017/jfm.2012.16
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Wetting front dynamics in an isotropic porous medium

Abstract: A new approach to the modelling of wetting fronts in porous media on the Darcy scale is developed, based on considering the types (modes) of motion the menisci go through on the pore scale. This approach is illustrated using a simple model case of imbibition of a viscous incompressible liquid into an isotropic porous matrix with two modes of motion for the menisci, the wetting mode and the threshold mode. The latter makes it necessary to introduce an essentially new technique of conjugate problems that allows … Show more

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Cited by 12 publications
(14 citation statements)
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“…In either trapping scenario, it should be expected that fluctuations in the aqueous flow field will give rise to additional stress fluctuations which, if large enough, will initiate either displacement of menisci though constrictions or movement of contact lines [23]. Those displacements or movements cause trapped phase mobilisation, and hence oil desaturation, at lower capillary numbers than expected through consideration of the steady state pressure gradient generated by steady viscoelastic flow alone.…”
mentioning
confidence: 99%
“…In either trapping scenario, it should be expected that fluctuations in the aqueous flow field will give rise to additional stress fluctuations which, if large enough, will initiate either displacement of menisci though constrictions or movement of contact lines [23]. Those displacements or movements cause trapped phase mobilisation, and hence oil desaturation, at lower capillary numbers than expected through consideration of the steady state pressure gradient generated by steady viscoelastic flow alone.…”
mentioning
confidence: 99%
“…14 Although the porous medium here occupies only a half-space, the flow entering it normally to its boundary has to turn around as this boundary is a streamline, so that in the porous medium one effectively has a flow round a corner. One has a similar situation once the wetting front propagating through a porous medium fragment as one section of it is brought to a halt, for example, as a result of it being stuck in the threshold mode of motion, 15 while the neighboring section continues to move ( Figure 1b). Then, on the Darcy scale, the advancing fluid appears to have a flow domain with a corner with the angle of 3p=2.…”
Section: Singularitymentioning
confidence: 99%
“…The situation becomes serious when what matters is not an integral but the values of the velocity. This happens, such as when one deals with two-phase flows where in the boundary conditions at the liquid-fluid interface 15,17 involve the velocity itself and not its integral. Then, the singularity in the velocity distribution becomes a major obstacle for the realistic modelling of the propagation of liquid-fluid interfaces in the situations where the flow becomes essentially two-dimensional.…”
Section: Singularitymentioning
confidence: 99%
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“…The Darcy equation (3) is written in the form already accounting for gravity with ρ being the density of the liquid, g the gravitational acceleration, z the coordinate directed against gravity, κ the permeability of the porous matrix and µ the liquid's viscosity; the coordinates are represented in terms of the position vector r; hereafter the pressure is measured with respect to the (presumed constant) pressure in the displaced gas. An appropriate starting point for the modelling is the recently developed approach [26] that gives boundary conditions for Laplace's equation for p,…”
Section: Macroscopic (Darcy-scale) Descriptionmentioning
confidence: 99%