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Interfacial area measurements for unsaturated flow through a porous medium
Author(s) -
Culligan Katherine A.,
Wildenschild Dorthe,
Christensen Britt S. B.,
Gray William G.,
Rivers Mark L.,
Tompson Andrew F. B.
Publication year - 2004
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/2004wr003278
Subject(s) - porous medium , saturation (graph theory) , multiphase flow , materials science , imbibition , mechanics , fluid dynamics , porosity , flow (mathematics) , synchrotron , mineralogy , geology , composite material , optics , physics , mathematics , germination , botany , combinatorics , biology
Multiphase flow and contaminant transport in porous media are strongly influenced by the presence of fluid‐fluid interfaces. Recent theoretical work based on conservation laws and the second law of thermodynamics has demonstrated the need for quantitative interfacial area information to be incorporated into multiphase flow models. We have used synchrotron based X‐ray microtomography to investigate unsaturated flow through a glass bead column. Fully three‐dimensional images were collected at points on the primary drainage curve and on the secondary imbibition and drainage loops. Analysis of the high‐resolution images (17 micron voxels) allows for computation of interfacial areas and saturation. Corresponding pressure measurements are made during the course of the experiments. Results show the fluid‐fluid interfacial area increasing as saturation decreases, reaching a maximum at saturations ranging from 20 to 35% and then decreasing as the saturation continues to zero. The findings support results of numerical studies reported in the literature.