Laboratory Tests of a Theory of Fingering during Infiltration into Layered Soils

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Laboratory Tests of a Theory of Fingering during Infiltration into Layered Soils

Ralph S. Baker^*

ENSR Consulting and Engineering, Acton, MA 01720

Daniel Hillel

Dep. of Plant and Soil Sciences, Univ. of Massachusetts, Amherst 01003

* Corresponding author.

ABSTRACT

A theory has recently been presented by Hillel and Baker toexplain and predict the occurrence of fingering and the fractionalwetted volume during infiltration into layered soils in termsof measurable hydraulic properties. When the conductivity ofa coarse-textured sublayer at its effective water-entry suctionis greater than the rate of transmission through a finer-texturedtop layer, the flow velocity increases across the interlayerplane. Thereupon, a spatially-distributed flow field in thetop layer will tend to constrict, forming spatially separatedstreams (fingers) in the sublayer. To test the hypothesis, pondedinfiltration experiments were conducted in transparent laboratorychambers packed with air-dry sands. The hydraulic propertiesof the media were determined by equilibrium capillary rise,parameter estimation, and horizontal absorption experiments.Dynamic measurements of flux and suction at the interlayer planeduring infiltration revealed that the effective water-entrysuction is characteristic of the predominant pore size in thesublayer and can be predicted from its median particle size(r² = 0.99). Predictions regarding the onset of fingering andthe wetted fractional volume of fingers were both validatedfor the monodisperse and polydisperse sublayers studied.

Received for publication March 16, 1989.

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