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Local thermodynamic description of isothermal single-phase flow in porous media

Darcy's law for porous media transport is given a new local thermodynamic basis in terms of the grand potential of confined fluids. The local effective pressure gradient is determined using non-equilibrium molecular dynamics, and the hydraulic conductivity and permeability are investigated. The transport coefficients are determined for single-phase flow in face-centered cubic lattices of solid spheres. The porosity changed from that in the closest packing of spheres to near unity in a pure fluid, while the fluid mass density varied from that of a dilute gas to a dense liquid. The permeability varied between \SI{5.7e-20}{\meter^2} and \SI{5.5e-17}{\meter^2}, showing a porosity-dependent Klinkenberg effect. Both transport coefficients depended on the average fluid mass density and porosity but in different ways. These results set the stage for a non-equilibrium thermodynamic investigation of coupled transport of multi-phase fluids in complex media.

preprint2022arXivOpen access
Olav GaltelandMichael T. RauterMina S. BratvoldThuat T. TrinhDick BedeauxSigne Kjelstrup
cond-mat.softphysics.chem-phphysics.flu-dyn
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Olav GaltelandMichael T. RauterMina S. BratvoldThuat T. TrinhDick BedeauxSigne Kjelstrup

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