Experiment on Water Infiltration and Solute Migration in Porous and Fractured Media

Jing Wen Song; Ming Yu Wang; Da Wei Tang

doi:10.4028/www.scientific.net/AMR.955-959.1993

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 955-959Experiment on Water Infiltration and Solute...

Experiment on Water Infiltration and Solute Migration in Porous and Fractured Media

Abstract:

The experiments were performed by considering the upper loose porous media and lower fractured media as a typical structure of vadose zones, and by constructing the corresponding physical model to simulate water flow and solute transport processes in order to investigate water flow features and migration mechanism. It has been indicated that in the porous and fractured complex media, if the lower fracture structure remains unchanged, the structure and permeability of the porous media offer considerable impact on infiltration processes. Additionally, if the structure and permeability of the porous media remain unchanged, the overall permeability and flow features of the fracture structure are significantly controlled by fracture configurations. Furthermore, for the fracture structures with different fracture configurations, it is indicated that increasing of the density of the vertical fractures results in much more enhancement of the solute concentration decay rate than that caused by increasing the density of the horizontal ones. This investigation was expected to be of scientific significance and practical value for effective groundwater protection.

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Periodical:

Advanced Materials Research (Volumes 955-959)

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1993-1997

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https://doi.org/10.4028/www.scientific.net/AMR.955-959.1993

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June 2014

Authors:

Jing Wen Song, Ming Yu Wang*, Da Wei Tang

Keywords:

Lab Experiment, Porous and Fractured Media, Solute Transport, Water Infiltration

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References

[1] Oda,M., 1985. Permeability tensor for discontinuous rock masses. Geotechnique, 35(4): 483–495.

DOI: 10.1680/geot.1985.35.4.483

Google Scholar

[2] Zhou Z.F., Gu,C.C., 1994. Research progress fracture water. Journal of hehai science and technology progress （1）：50-55. (in Chinese).

Google Scholar

[3] Witherspoon P.A., Wang J.S.Y., Iwai, K., et. al., 1980. Validity of cubic law for fluid flow in deformable rock fracture. Water Resource, 16(6): 1016–1024.

DOI: 10.1029/wr016i006p01016

Google Scholar

[4] Zhou Z.F., Wang J.G., 2004. Fractured media hydrodynamics. China Water Power Press , BJ, 13-41. (in Chinese).

Google Scholar

[5] Long J.C.S., Witherspoon P.A., 1985. The relationship of the degree of interconnection to permeability in fractured networks. Journal of Geophysical Research: Solid Earth, 90(b4): 3097-3094.

DOI: 10.1029/jb090ib04p03087

Google Scholar

[6] Wang M.Y., Kulatilake P.H.S.W., 2008. Understanding of Hydraulic Properties from Configurations of Stochastically Distributed Fracture Networks. Hydrological Processes, 22(8): 1125-1135.

DOI: 10.1002/hyp.6667

Google Scholar