Physics of hydrophobic soils

T. W.J. Bauters; T. S. Steenhuis; D. A. DiCarlo; J. L. Nieber; L. W. Dekker; C. J. Ritsema; J. Y. Parlange; R. Haverkamp

doi:10.1016/B978-0-444-51269-7.50022-9

Physics of hydrophobic soils

T. W.J. Bauters, T. S. Steenhuis, D. A. DiCarlo, J. L. Nieber, L. W. Dekker, C. J. Ritsema, J. Y. Parlange, R. Haverkamp

Bioproducts and Biosystems Engineering

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8 Scopus citations

Abstract

Although it is generally well known that water repellent soils have distinct preferential flow patterns, the physics of this phenomenon is not well understood. In this chapter, we show that water repellency affects the soil water contact angle and this, in turn, has a distinct effect on the constitutive relationships during imbibing. Using these constitutive relationships, unstable flow theory developed for coarse grained soils can be used to predict the shape and water content distribution for water repellent soils. A practical result of this paper is that with a basic experimental setup, we can characterize the imbibing front behavior by measuring the water entry pressure and the imbibing soil characteristic curve from the same heat treated soil.

Original language	English (US)
Title of host publication	Soil Water Repellency
Subtitle of host publication	Occurrence, Consequences, and Amelioration
Publisher	Elsevier Inc.
Pages	215-224
Number of pages	10
ISBN (Print)	9780444512697
DOIs	https://doi.org/10.1016/B978-0-444-51269-7.50022-9
State	Published - Apr 2003

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title = "Physics of hydrophobic soils",

abstract = "Although it is generally well known that water repellent soils have distinct preferential flow patterns, the physics of this phenomenon is not well understood. In this chapter, we show that water repellency affects the soil water contact angle and this, in turn, has a distinct effect on the constitutive relationships during imbibing. Using these constitutive relationships, unstable flow theory developed for coarse grained soils can be used to predict the shape and water content distribution for water repellent soils. A practical result of this paper is that with a basic experimental setup, we can characterize the imbibing front behavior by measuring the water entry pressure and the imbibing soil characteristic curve from the same heat treated soil.",

author = "Bauters, {T. W.J.} and Steenhuis, {T. S.} and DiCarlo, {D. A.} and Nieber, {J. L.} and Dekker, {L. W.} and Ritsema, {C. J.} and Parlange, {J. Y.} and R. Haverkamp",

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T1 - Physics of hydrophobic soils

AU - Bauters, T. W.J.

AU - Steenhuis, T. S.

AU - DiCarlo, D. A.

AU - Nieber, J. L.

AU - Dekker, L. W.

AU - Ritsema, C. J.

AU - Parlange, J. Y.

AU - Haverkamp, R.

PY - 2003/4

Y1 - 2003/4

N2 - Although it is generally well known that water repellent soils have distinct preferential flow patterns, the physics of this phenomenon is not well understood. In this chapter, we show that water repellency affects the soil water contact angle and this, in turn, has a distinct effect on the constitutive relationships during imbibing. Using these constitutive relationships, unstable flow theory developed for coarse grained soils can be used to predict the shape and water content distribution for water repellent soils. A practical result of this paper is that with a basic experimental setup, we can characterize the imbibing front behavior by measuring the water entry pressure and the imbibing soil characteristic curve from the same heat treated soil.

AB - Although it is generally well known that water repellent soils have distinct preferential flow patterns, the physics of this phenomenon is not well understood. In this chapter, we show that water repellency affects the soil water contact angle and this, in turn, has a distinct effect on the constitutive relationships during imbibing. Using these constitutive relationships, unstable flow theory developed for coarse grained soils can be used to predict the shape and water content distribution for water repellent soils. A practical result of this paper is that with a basic experimental setup, we can characterize the imbibing front behavior by measuring the water entry pressure and the imbibing soil characteristic curve from the same heat treated soil.

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SN - 9780444512697

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BT - Soil Water Repellency

PB - Elsevier Inc.

ER -

Physics of hydrophobic soils

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