Capillary hysteresis and gravity segregation in two phase flow through porous media

K. Mitra; C.J. van Duijn

doi:10.1007/s10596-021-10106-6

Capillary hysteresis and gravity segregation in two phase flow through porous media

K. Mitra (Corresponding author), C.J. van Duijn

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Abstract

We study the gravity driven flow of two fluid phases in a one dimensional homogeneous porous column when history dependence of the pressure difference between the phases (capillary pressure) is taken into account. In the hyperbolic limit, solutions of such systems satisfy the Buckley-Leverett equation with a non-monotone flux function. However, solutions for the hysteretic case do not converge to the classical solutions in the hyperbolic limit in a wide range of situations. In particular, with Riemann data as initial condition, stationary shocks become possible in addition to classical components such as shocks, rarefaction waves and constant states. We derive an admissibility criterion for the stationary shocks and outline all admissible shocks. Depending on the capillary pressure functions, flux function and the Riemann data, two cases are identified a priori for which the solution consists of a stationary shock. In the first case, the shock remains at the point where the initial condition is discontinuous. In the second case, the solution is frozen in time in at least one semi-infinite half. The predictions are verified using numerical results.

Original language	English
Pages (from-to)	101-114
Number of pages	14
Journal	Computational Geosciences
Volume	26
Issue number	1
DOIs	https://doi.org/10.1007/s10596-021-10106-6
Publication status	Published - Feb 2022

Funding

K. Mitra acknowledges the support from Radboud University. Parts of the research for K. Mitra were also funded by INRIA Paris through the ERC Gatipor grant, TU Dortmund University, Shell–NWO CSER program(grant 14CSER016) and Hasselt University (grant BOF17BL04). C.J. van Duijn is supported by the Darcy Center of Eindhoven University of Technology and Utrecht University. The authors would like to thank Prof. Sorin Pop for many fruitful discussions on the topic. The data and models used in this paper are publicly available and have been properly referenced.

Funders	Funder number
Eindhoven University of Technology
Institut National de Recherche en Informatique et en Automatique
Shell
H2020 European Research Council
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	14CSER016
Radboud University Medical Center
Hasselt University	BOF17BL04
Technische Universität Dortmund

Keywords

Admissibility criteria of shocks
Buckley-Leverett
Gravity segregation
Hysteresis
Jump in saturation
Riemann data
Stationary shock

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abstract = "We study the gravity driven flow of two fluid phases in a one dimensional homogeneous porous column when history dependence of the pressure difference between the phases (capillary pressure) is taken into account. In the hyperbolic limit, solutions of such systems satisfy the Buckley-Leverett equation with a non-monotone flux function. However, solutions for the hysteretic case do not converge to the classical solutions in the hyperbolic limit in a wide range of situations. In particular, with Riemann data as initial condition, stationary shocks become possible in addition to classical components such as shocks, rarefaction waves and constant states. We derive an admissibility criterion for the stationary shocks and outline all admissible shocks. Depending on the capillary pressure functions, flux function and the Riemann data, two cases are identified a priori for which the solution consists of a stationary shock. In the first case, the shock remains at the point where the initial condition is discontinuous. In the second case, the solution is frozen in time in at least one semi-infinite half. The predictions are verified using numerical results.",

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AB - We study the gravity driven flow of two fluid phases in a one dimensional homogeneous porous column when history dependence of the pressure difference between the phases (capillary pressure) is taken into account. In the hyperbolic limit, solutions of such systems satisfy the Buckley-Leverett equation with a non-monotone flux function. However, solutions for the hysteretic case do not converge to the classical solutions in the hyperbolic limit in a wide range of situations. In particular, with Riemann data as initial condition, stationary shocks become possible in addition to classical components such as shocks, rarefaction waves and constant states. We derive an admissibility criterion for the stationary shocks and outline all admissible shocks. Depending on the capillary pressure functions, flux function and the Riemann data, two cases are identified a priori for which the solution consists of a stationary shock. In the first case, the shock remains at the point where the initial condition is discontinuous. In the second case, the solution is frozen in time in at least one semi-infinite half. The predictions are verified using numerical results.

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Capillary hysteresis and gravity segregation in two phase flow through porous media

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