Dynamic Water-Entry Pressure for Initially Dry Glass Beads and Sea Sand

doi:10.2113/4.1.127

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Dynamic Water-Entry Pressure for Initially Dry Glass Beads and Sea Sand

Takeyuki Annaka^* and Susumu Hanayama

Faculty of Agriculture, Yamagata University, Tsuruoka, Yamagata 997-8555, Japan
^* Corresponding author (annakt{at}tds1.tr.yamagata-u.ac.jp)

Received 6 April 2004.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

Dynamic water-entry pressure has been considered an importantfactor in the mechanism of fingered flow formation. We measuredand compared dynamic water-entry pressures of air-dried glassbeads of 0.4-mm mean particle size and for 0.30- to 0.60-mm(30–50 mesh) sea sand. Two measurements were conducted.First, breakthrough pressures were measured by increasing thesupply water pressure incrementally from a low water pressureat which water could not enter the porous medium. Second, therelationship between the supply water pressure and the initialinfiltration rate was measured by keeping the supply water pressureconstant at several values. Measured values for the 0.4-mm glassbeads and the 30- to 50-mesh sea sand showed some differences.While the breakthrough pressure was similar to the advancingcapillary pressure for both materials, only the 30- to 50-meshsea sand showed almost the same value as the water pressureat the inflection point on the initial wetting curve. For the0.4-mm glass beads, the breakthrough pressure was higher (lessnegative) than that of the inflection point. Furthermore, the0.4-mm glass beads showed a sharp jump in the initial infiltrationrate when the supply water pressure exceeded the breakthroughpressure, whereas the 30- to 50-mesh sea sand showed an almostlinear increase in the initial infiltration rate. These differencesare discussed in terms of oscillatory nature of the water-entrypressure. An expression for the dynamic water-entry pressurewas fitted to the measured data. The expression was used forestimating the width of fingers formed in the materials duringinfiltration into layered conditions and was found to be usefulfor studying fingered flow formation, at least for the glassbeads.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

WETTING FRONT INSTABILITY is one of the mechanisms that producepreferential flow, which causes nonuniform water distributionin a soil profile and potentially rapid transport of contaminantsto the groundwater. According to the criteria of wetting frontinstability (Raats, 1973; Philip, 1975), wetting fronts formedduring infiltration become unstable when the infiltration rateis less than the hydraulic conductivity of the soil, or whenthe gradient in the water pressure head behind the wetting frontis opposed to the flow. When the wetting front becomes unstable,small perturbations on the front will grow into fingers, whichthen govern water and solute movement in the soil profile.

A large number of studies have been carried to decipher theimportant effects of finger size and water content within thefinger on water and solute movement in soil profiles. Linearinstability analyses (e.g., Philip, 1975; Parlange and Hill, 1976)and dimensional analyses in conjunction with systematicexperiments (Glass et al., 1989a, 1989b) have been used to estimatefinger size. Water content and water pressure distributionswithin the finger have also been analyzed (Selker et al., 1992;Nieber, 1996). However, more accurate prediction of such fingerproperties requires thorough understanding of the finger formationprocess, that is, the mechanism of fingered flow. Until now,this process has been considered mainly in terms of the Darcy–Buckinghamflux equation, hysteretic moisture retention functions, andthe water-entry pressure (Hillel and Baker, 1988; Glass et al., 1989c;Nieber, 1996; Geiger and Durnford, 2000).

Among those factors, the water-entry pressure may be the mostimportant in the finger formation process because of its rolein determining the boundary condition at the wetting front.Hillel and Baker (1988) treated the water-entry pressure asa single, characteristic value for air-dried porous media, anddiscussed the important role of the water-entry pressure inthe formation of fingered flow. By means of infiltration experimentsinto fine-over-coarse layered sands, Baker and Hillel (1990)showed that the water-entry pressure has almost the same valueas the inflection point on the wetting curve. Recently, Wang et al. (2000)measured the water-entry pressure with a waterponding method for water-repellent soil and with a tension-pressureinfiltrometer method for both water-repellent and wettable soils.

The concept of dynamic water-entry pressure, which considersthe water-entry pressure as an increasing function of flux,has often been used to better understand mechanism of the fingeredflow generation (Geiger and Durnford, 2000; DiCarlo and Blunt, 2000).Geiger and Durnford (2000) measured the soil water pressurehead near the wetting front for various flux rates for initiallyair-dried soil conditions and presented a mechanistic modelthat explained soil water pressure gradients of stable and unstableflow in homogeneous soils. Using the concept of dynamic water-entrypressure, DiCarlo and Blunt (2000) obtained a self-similar solutionto a moving finger with a curved interface. From this solutionthey found analytical expressions for the shape and width offully developed gravitationally driven fingers.

While the water-entry pressure can be estimated indirectly fromthe wetting curve (Wang et al., 2000), direct measurement ofthe water-entry pressure is still important to clarify the fingeredflow processes because dynamic effects of the moving water–airinterface in porous media are not very well understood at present.The objectives of this study were (i) to measure the dynamicwater-entry pressure for initially air-dried glass beads andsea sand having almost the same mean particle size and (ii)to compare and discuss the measured values.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

Materials
Figure 1 shows the particle shapes of the glass beads andthe sea sand (Wako Pure Chemical Industries, Ltd., Osaka, Japan)used in this study. Both materials were soaked in dilute hydrochloricacid, rinsed well with distilled water, and then air-dried.Physical properties of the materials are shown in Table 1. Theparticle size distributions, as well as the particle shapesas shown in Fig. 1, differ between the two materials. Whilethe mean particle size of the 30- to 50-mesh sea sand is slightlylarger than that of the 0.4-mm glass beads, the saturated hydraulicconductivity of the sea sand is lower than that of the glassbeads.

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Fig. 1. Photographs of the particle shapes for the materials used in the experiment.

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Table 1. Physical properties of glass beads and sea sand used in this study.

Measurement of Dynamic Water-Entry Pressure
Water-entry pressures can be evaluated in two ways. One methodis to consider it as a breakthrough pressure, that is, the criticalwater pressure at which water starts to enter the porous medium(Hillel and Baker, 1988; Baker and Hillel, 1990; Wang et al., 2000).Another method is to consider it as the relationshipbetween water flux and water pressure at the wetting front,that is, as the dynamic water-entry pressure (Geiger and Durnford, 2000).In this study, we measured both the breakthrough pressureand the flux–pressure relationship for the materials toevaluate the dynamic water-entry pressure.

Figure 2 shows the apparatus used to measure dynamic water-entrypressure, as proposed by Idesawa and Annaka (1996). The apparatusconsisted of an acrylic cell filled with air-dried particles,a Mariotte reservoir for water supply, and an electric balanceto measure the cumulative amount of water supply. A filter wasneeded to establish contact between the porous medium in thecell and the supply water of negative pressure. A necessaryproperty of the filter is that it have an air-entry pressurelower (more negative) than that of the porous medium and a permeabilitythat does not substantially limit water-entry. For the 0.4-mmglass beads we used a 0.1-mm-thick cloth filter, which has goodpermeability and a higher (less negative) air-entry pressure.However, the filter could not be used for the 30- to 50-meshsea sand because its air-entry pressure was higher (less negative)than that of the sand. Instead, a 0.02-mm-thick membrane filter,which has a lower air-entry pressure but is less permeable thanthe cloth filter, had to be used for the sea sand.

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Fig. 2. Apparatus for measuring dynamic water-entry pressure.

The acrylic cell was turned upside down and then immersed ina distilled water bath to fill the water pool with distilledwater. After filling the water pool, the cell was connectedto the Mariotte reservoir with a tube and removed from the waterbath. Excess water on the filter was removed carefully withtissues, after which the cell was filled with air-dried material,either the 30- to 50-mesh sea sand or the 0.4-mm glass beads.A piece of gauze was placed on the surface of the sample, andthe cell was capped. The cell was subsequently inverted, fixedwith a stand, and placed on a laboratory jack, as shown in Fig. 2.

Using the apparatus, two types of measurement were conducted.With the supply water pressure increasing incrementally, wefirst measured the breakthrough pressure (i.e., the point atwhich water started to enter the dry sample). Our method forthis measurement was similar to that of Wang et al. (2000),who first introduced tension-pressure infiltrometer method tomeasure the water-entry value. We began with a water pressurelow enough for the supply water not to enter the sample: –9cm for the 0.4-mm glass beads and –20 cm for the 30- to50-mesh sea sand. If water did not appear to enter the samplefor 1 min, the laboratory jack was operated to increase thesupply water pressure by 1 cm. This process was repeated untilthe onset of water-entry was observed. When water-entry wasobserved, the vertical difference ${Delta}$ H (Fig. 2) was measured witha cathetometer, and the supply water pressure – ${Delta}$ H was consideredto be the breakthrough pressure. This measurement was repeatedsix times for each material.

Next, we measured cumulative infiltration under constant supplywater pressures. From the data involving temporal changes inthe cumulative infiltration, we calculated a time-averaged fluxfor the first 1 min to obtain the dependence of the flux onthe supply water pressure. For each measurement, we repackedthe cell with the dry sample.

Characteristic curves for initial wetting from the air-driedcondition were obtained using a soil column method (Nakano et al., 1995).The soil column for each material was allowed towet by capillary rise until equilibrium was reached. The columnwas subsequently sampled at 1-cm intervals for the glass beadsand at 2-cm intervals for the sea sand, and the water contentsof the sections were determined by oven drying. In addition,we estimated the advancing capillary pressure head, that is,the water pressure head at the wetting front as it moves duringinfiltration (Green and Ampt, 1911), for the dry samples byfitting the Green–Ampt equation to measured data obtainedfrom ponded infiltration experiments.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

Breakthrough Pressure
Table 2 shows the ranges and means of the measured breakthroughpressure values. The advancing capillary pressure values arealso shown. The breakthrough pressures of the 0.4-mm glass beadsare clearly higher than those of the 30- to 50-mesh sea sand,even though the particle size of the glass beads is smallerthan that of the sea sand. Furthermore, the value of the breakthroughpressure is almost the same as that of the advancing capillarypressure for both materials. This similarity between the breakthroughand the advancing capillary pressure values suggests that thefilter effects were negligible for both materials.

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Table 2. Ranges and means of the measured breakthrough pressure values.

Figure 3 shows initial wetting curves for both materials,obtained by wetting from air-dried condition. For the 30- to50-mesh sea sand, the breakthrough pressure was about –10cm, which indeed corresponded to the inflection point on thewetting curve, as reported by Baker and Hillel (1990). On theother hand, the –2.2-cm breakthrough pressure for the0.4-mm glass beads substantially differed from the –7-cmwater pressure at the inflection point.

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Fig. 3. Initial wetting curves for both materials.

Relationship between Supply Water Pressure and Initial Infiltration Rate
Figure 4 shows temporal changes in the cumulative infiltrationfor several supply water pressures. For the 0.4-mm glass beadsat supply water pressures less than –2.3 cm, the cumulativeinfiltration increased very slowly at first, followed by a rapidincrease. Such temporal change patterns for cumulative infiltrationstrongly depended on the supply water pressure. Elapsed timeto the rapid increase in the cumulative infiltration was 8 to9 min for the –2.6-cm supply water pressure, 3 to 4 minfor –2.5 cm, and almost zero for –2.3 cm. This rapidincrease in the cumulative infiltration was accompanied by thegrowth of a narrow finger in the medium. On the other hand,the cumulative infiltration for the 30- to 50-mesh sea sand,for all supply water pressures, showed an almost linear increasewith time, and no temporal change as for the 0.4-mm glass beads.Finger growth was also observed for the sea sand, but the fingerwas wider than that for the glass beads.

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Fig. 4. Temporal changes in the cumulative infiltration for several supply water pressures: (a) for the 0.4-mm glass beads (a very slow increase is followed by a rapid increase at supply water pressures less than –2.3 cm) and (b) for the 0.30- to 0.60-mm (30–50 mesh) sea sand (a nearly linear increase in the cumulative infiltration with time).

Figure 5 shows the relationships between the supply waterpressure and a time-averaged infiltration rate during the firstminute, which we refer to as the initial infiltration rate.This infiltration rate was calculated from the cumulative infiltrationdata at 1 min. For the 0.4-mm glass beads, the initial infiltrationrate was almost zero when the supply water pressure was lowerthan –2.5 cm. However, the infiltration rate showed arapid increase at a supply water pressure of –2.4 cm.By comparison, the initial infiltration rate for the 30- to50-mesh sea sand increased almost linearly with the supply waterpressure. The curves in Fig. 5 may be used to explain differencesin the temporal change in cumulative infiltration shown in Fig. 4.When the supply water starts to enter the dry sample, a wettingfront forms and begins to move downward. The water pressureat the wetting front then becomes higher due to the gravitationalforce. Thus, even when the supply water pressure is lower thanthe breakthrough pressure, the water pressure at the wettingfront can exceed the breakthrough pressure. From this fact andthe relationships shown in Fig. 5, we can expect a rapid increasein the infiltration rate, and hence cumulative infiltration,for the 0.4-mm glass beads. The cumulative infiltration forthe 30- to 50-mesh sea sand, however, should not change similarlyin time as for the glass beads since the relationship for thesea sand shows a linear increase in the infiltration rate withincreasing supply water pressure.

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Fig. 5. Relationships between supply water pressure and initial infiltration rate. The initial infiltration rate is the time averaged rate during the first minute after the sample had contact with the supply water.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

Breakthrough Pressure
While the breakthrough pressure was nearly the same as the advancingcapillary pressure for both materials (Table 2), the breakthroughpressure was essentially the same as the water pressure at theinflection point on the initial wetting curve only for the 30-to 50-mesh sea sand (Fig. 3). For the 0.4-mm glass beads, thebreakthrough pressure was higher (less negative) than the correspondingpressure at the inflection point, which indicates that the glassbeads have a relatively large water pressure range over whichsupply water cannot enter instantaneously. Figure 3 shows asharp transition from completely dry to saturation over a fairlysmall change in the water pressure for the 0.4-mm glass beads,and a smooth continuous variation in saturation as the waterpressure increases for the 30- to 50-mesh sea sand. This differencemay be attributed to differences in particle shape and sizedistribution for the materials shown in Fig. 1, since theseproperties determine the behavior of the water–air interfaceand the breakthrough pressure. Lu et al. (1995) proposed a modelfor the capillary force acting on pore-scale water–airinterfaces, where the capillary force oscillates from a minimumat the largest throat to a maximum at the neck as the water–airinterface advances, to include entrapping the particle aheadof the interface and making the pore saturated. Provided thatthe interfaces at individual pores behave in such a manner,a continuous macroscopic water–air interface (i.e., asaturated wetting front) should be formed. This saturated wettingfront may cause the creation of a breakthrough pressure, whichis not identical to a temporal and spatial average of individualpore capillary pressures. On the other hand, the breakthroughpressure for the 30- to 50-mesh sea sand, which is identicalto the water pressure at the inflection point, may be consideredto be a temporal and spatial average of individual pore capillarypressures. However, the exact behavior of the water–airinterfaces and the capillary pressures in these porous media,and what causes the two media to behave differently, needs morestudy.

Expression for the Dynamic Water-Entry Pressure and its Application to Finger Width Estimation
Weitz et al. (1987) measured the dynamic capillary pressureP_c vs. the interface velocity for a water–oil interfacein 0.5-mm-diameter glass beads and found that an empirical expressionfitted the data well. For the water–air interface, whereP_c is considered to be the dynamic water-entry pressure, theexpression can be written as

[1]
where ${sigma}$ /r_p is the breakthrough pressure for the medium, ${sigma}$ is the surfacetension of water, r_p is some characteristic pore radius, ${alpha}$ andß are fitting constants, and N_Ca is the capillarynumber, which is defined as the ratio of the viscous force tothe interfacial force (e.g., Hoffman, 1975). Following Friedman (1999),the capillary number for a saturated wetting front ina porous medium can be written as

[2]
whereµ is the viscosity of water, q is the water flux, and ${theta}$ _s is the saturated volumetric water content. Using the saturatedhydraulic conductivity K_s and the expressions for the water-entryand breakthrough pressures, and modifying the constant termto include pore-entry pressure fluctuations (DiCarlo and Blunt, 2000),we obtain

[3]
where h_c is thedynamic water-entry pressure head, h_br is the breakthrough pressurehead, ${delta}$ gives the size of the entry pressure fluctuations, and ${alpha}$ ' = ${alpha}$ (µK_s/ ${sigma}$ ${theta}$ _s)^ß. This equation shows the relationshipbetween the dynamic water-entry pressure scaled by the absolutevalue of the breakthrough pressure and the infiltration ratenormalized by the saturated conductivity of the porous medium.Values of the fitted constants as reported by Weitz et al. (1987)for the water–oil interface in sintered glass beads 0.5mm in diameter were ${alpha}$ ${approx}$ 300 and ß ${approx}$ 0.5. For the sameexperimental setup, except for the interface velocity, Stokes et al. (1988)obtained a similarly good relationship betweenP_c and the interface velocity at low velocities, for which fittedvalues were ${alpha}$ ${approx}$ 1.0 x 10⁴ and ß ${approx}$ 1 (DiCarlo and Blunt, 2000).Figure 6 shows the normalized relationship betweenthe infiltration rate and the supply water pressure for ourexperiment, originally shown in Fig. 5. By fitting Eq. [3] tothe measured values, fitted constants were determined for bothmaterials. For the 0.4-mm glass beads, we obtained ${delta}$ = 0.18, ${alpha}$ ' = 0.53 ( ${alpha}$ = 11), and ß = 0.30. However, for the 30-to 50-mesh sea sand, we found ${delta}$ = 0.10, ${alpha}$ ' = 5.5 ( ${alpha}$ = 2.4 x 10⁴),and ß = 0.79. Differences in the values of fittedconstants between the 0.4-mm glass beads and the 30- to 50-meshsea sand are relatively large, especially for the ${alpha}$ value. Atpresent, we are unable to give a good explanation for thesedifferences.

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Fig. 6. Normalized relationship between the supply water pressure and the initial infiltration rate, with the infiltration rate being normalized by the saturated hydraulic conductivity of the medium, and the supply water pressure scaled by the absolute value of the breakthrough pressure as shown in Table 2. Fitted lines are also shown for both materials.

The above difference in the dynamic water-entry pressure betweenthe two materials can cause pronounced differences in the formationof fingers. Figure 7 shows two-dimensional fingered flow patternsformed in the 0.4-mm glass beads and the 30- to 50-mesh seasand for similar fine-over-coarse layered conditions in whichglass beads of 0.05-mm particle diameter were used for the toplayer. From the figure we can estimate the width of fully developedfingers, which is about 1 cm for the glass beads and 5 to 7cm for the sea sand. After DiCarlo and Blunt (2000), an expressionfor the finger width (d) can be written as

[4]

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Fig. 7. Fingered flow formed in the 0.4-mm glass beads and the 0.30- to 0.60-mm (30–50 mesh) sea sand during infiltration for fine-over-coarse layered conditions. Width and height of the layers were about 30 cm.

Assuming q/K_s = 0.05, which is almost the same flux as for theexperiments, Eq. [4] gives d = 1.1 cm for the glass beads andd = 11.3 cm for the sea sand using the fitted values of h_br, ${alpha}$ ', ß, and ${delta}$ for each material. For the 0.4-mm glassbeads, the estimated value agrees well with the measured one.However, the estimated value for the 30- to 50-mesh sea sandwas about two times larger than the measured value. The firstterm of the right-hand side of Eq. [4] expresses the dynamiccomponent of the finger width, while the second term expressesthe static component (DiCarlo and Blunt, 2000). Since the dynamicand static components were estimated to be 9.2 and 2.1 cm, respectively,the dynamic component is considered to be overestimated. Whileit is not clear why the dynamic component was overestimatedfor the 30- to 50-mesh sea sand, the assumption of having asaturated wetting front may not have been satisfied for thesea sand. These results suggest that the expressions for thedynamic water-entry pressure, Eq. [3], and the finger width,Eq. [4], are useful for studying the mechanisms of fingeredflow, at least for the air-dried glass beads in which saturatedwetting front is formed during infiltration.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

Dynamic water-entry pressures, based on both breakthrough pressuresand relationships between the supply water pressure and theinitial infiltration rate, were measured and compared for air-driedglass beads having 0.4-mm mean particle size and 0.30- to 0.60-mm(30–50 mesh) sea sand. The following differences wereobserved:

The breakthrough pressure, which was almost identicalto theadvancing capillary pressure for both materials, correspondedto the water pressure at the inflection point of the initialwetting curve for the 30- to 50-mesh sea sand, but not for the0.4-mm glass beads.
The 0.4-mm glass beads showed a sharpjump in the initial infiltrationrate when the supply waterpressure exceeded the breakthroughpressure, whereas the 30-to 50-mesh sea sand showed an almostlinear increase.

The differences between the breakthrough pressures and the inflectionpoints on the initial wetting curve were discussed in termsof the oscillatory nature of the water-entry pressure in air-driedglass beads. An expression for the dynamic water-entry pressure(after Weitz et al., 1987) was fitted to the experimental data.Following DiCarlo and Blunt (2000), fully developed finger widthswere estimated for the infiltration experiments and comparedwith the experimental results; they showed good agreement forthe 0.4-mm glass beads.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
REFERENCES

Baker, R.S., and D. Hillel. 1990. Laboratory tests of a theory of fingering during infiltration into layered soils. Soil Sci. Soc. Am. J. 54:20–30.[Abstract/Free Full Text]

DiCarlo, D.A., and M.J. Blunt. 2000. Determination of finger shape using the dynamic capillary pressure. Water Resour. Res. 36:2781–2785.

Friedman, S.P. 1999. Dynamic contact angle explanation of flow rate-dependent saturation-pressure relationships during transient liquid flow in unsaturated porous media. J. Adhes. Sci. Technol. 13:1495–1518.

Geiger, S.L., and D.S. Durnford. 2000. Infiltration in homogeneous sands and a mechanistic model of unstable flow. Soil Sci. Soc. Am. J. 64:460–469.[Abstract/Free Full Text]

Glass, R.J., J.-Y. Parlange, and T.S. Steenhuis. 1989a. Wetting front instability: 1. Theoretical discussion and dimensional analysis. Water Resour. Res. 25:1187–1194.

Glass, R.J., T.S. Steenhuis, and J.-Y. Parlange. 1989b. Wetting front instability: 2. Experimental determination of relationships between system parameters and two-dimensional unstable flow field behavior in initially dry porous media. Water Resour. Res. 25:1195–1207.

Glass, R.J., T.S. Steenhuis, and J.-Y. Parlange. 1989c. Mechanism for finger persistence in homogeneous, unsaturated porous media: Theory and verification. Soil Sci. 148:60–70.

Green, W.H., and G.A. Ampt. 1911. Studies on soil physics. Part 1. The flow of air and water through soils. J. Agric. Sci. 4:1–24.

Hillel, D., and R.S. Baker. 1988. A descriptive theory of fingering during infiltration into layered soils. Soil Sci. 146:51–56.

Hoffman, R.L. 1975. A study of the advancing interface. 1. Interface shape in liquid-gas system. J. Colloid Interface Sci. 50:228–241.

Idesawa, S., and T. Annaka. 1996. Growth of fingers due to wetting front instability and the mechanism of finger persistence. 2. Physical features of water penetration into packed glass beads and water entry threshold. Trans. JSIDRE 186:1–6.

Lu, T.X., D.R. Nielsen, and J.W. Biggar. 1995. Water movement in glass bead porous media. 3. Theoretical analysis of capillary rise into initially dry media. Water Resour. Res. 31:11–18.

Nakano, M., T. Miyazaki, S. Shiozawa, and T. Nishimura. 1995. Physical and environmental analysis of soils. University of Tokyo Press, Tokyo.

Nieber, J.L. 1996. Modeling finger development and persistence in initially dry porous media. Geoderma 70:207–229.[ISI]

Parlange, J.-Y., and D.E. Hill. 1976. Theoretical analysis of wetting front instability in soils. Soil Sci. 122:236–239.

Philip, J.R. 1975. Stability analysis of infiltration. Soil Sci. Soc. Am. Proc. 39:1042–1049.

Raats, P.A.C. 1973. Unstable wetting fronts in uniform and nonuniform soils. Soil Sci. Soc. Am. Proc. 37:681–685.

Selker, J., J.-Y. Parlange, and T.S. Steenhuis. 1992. Fingered flow in two dimensions: 2. Predicting finger moisture profile. Water Resour. Res. 28:2523–2528.

Stokes, J.P., A.P. Kushnick, and M.O. Robbins. 1988. Interface dynamics in porous media: A random-field description. Phys. Rev. Lett. 60:1386–1389.[Medline]

Wang, Z., L. Wu, and Q.J. Wu. 2000. Water-entry value as an alternative indicator of soil water-repellency and wettability. J. Hydrol. (Amsterdam) 231–232:76–83.

Weitz, D.A., J.P. Stokes, R.C. Ball, and A.P. Kushnick. 1987. Dynamic capillary pressure in porous media: Origin of the viscous-fingering length scale. Phys. Rev. Lett. 59:2967–2970.[Medline]

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