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EXTRACTION OF DENSITY-LAYERED FLUID FROM A POROUS MEDIUM

Part of: Flows in porous media; filtration; seepage Incompressible inviscid fluids

Published online by Cambridge University Press:  07 March 2024

JYOTHI JOSE Open the ORCID record for JYOTHI JOSE [Opens in a new window]
JYOTHI JOSE*
Affiliation:
School of Mathematics and Statistics, Murdoch University, 90 South Street, Murdoch, WA 6150, Australia
*
e-mail: jyothijose2011@gmail.com
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Abstract

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Keywords

porous mediafluid flowdensity stratificationspectral methodsupercritical solutionsexact solutionscritical flux valueoil recoveryaquifers

MSC classification

Primary: 76S99: None of the above, but in this section
Secondary: 76B07: Free-surface potential flows 76B70: Stratification effects in inviscid fluids 76S05: Flows in porous media; filtration; seepage
Type
PhD Abstract
Information
Bulletin of the Australian Mathematical Society , Volume 109 , Issue 3 , June 2024 , pp. 594 - 595
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Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Australian Mathematical Publishing Association Inc.

Flow of fluids in porous media is very important across a range of applications. Oil recovery from underground, pumping fresh water from aquifers and mineral leaching in mining applications are obvious examples. A characteristic of the fluids in many of these applications is that they are stratified in density, either due to fluid properties (oil-water), salt content (fresh-water, salt-water) or temperature.

We consider axisymmetric flow towards a point sink from a stratified fluid in a vertically confined aquifer. We present two approaches to solve the equations of flow for the linear density gradient case. First, a series method results in an eigenfunction expansion in Whittaker functions. The second method is a finite difference method. Comparison of the two methods verifies the finite difference method is accurate, so that more complicated nonlinear, density stratification can be considered. Interesting results for the case where the density stratification changes from linear to almost two- layer are presented, showing that in the nonlinear case, there are certain values of flow rate for which a steady solution does not occur. A spectral method is then implemented to consider cases in which there is a stagnant region beneath a sharp interface between two layers of different, but constant density. In this situation, flows also exist only for flow rates beneath a critical flux value, consistent with the results for the continuous density stratification. Finally, we considered supercritical solutions, in which both layers flow out through the sink, using a modified spectral method. We found two exact solutions, one in which the sink is at the middle height of the interface and another in the limit as the flow rate becomes large. For all other flow rates, we found a numerical solution. As the sink moves away from the initial value of the interface height, the required critical flow rate that induces coning and results in supercritical flow increases significantly. This result is consistent with the results of the single-layer case.

Some of this research has been published in [Reference Jose, Hocking and Farrow1, Reference Jose, Hocking and Farrow2].

Footnotes

Thesis submitted to Murdoch University in January 2023; degree approved on 16 August 2023; supervisor Graeme Hocking, co-supervisor Duncan Farrow.

References

Jose, J., Hocking, G. and Farrow, D., ‘Extraction of density-layered fluid from a porous medium’, ANZIAM J. 61 (2020), C137C151.CrossRefGoogle Scholar
Jose, J., Hocking, G. and Farrow, D., ‘Extraction of density-layered fluid from a porous medium’, J. Engrg. Math. 135 (2022), Article no. 3, 18 pages.CrossRefGoogle Scholar