The Pressure Head Regime in the Induction Zone During Unstable Nonponding Infiltration: Theory and Experiments

doi:10.2136/vzj2004.0158

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The Pressure Head Regime in the Induction Zone During Unstable Nonponding Infiltration

Theory and Experiments

H. Cho^a, G. H. de Rooij^b^,* and M. Inoue^c

^a Dep. of Agricultural Sciences, Saga Univ., Honjou 1, Saga-shi 840-8502, Japan
^b Dep. Environmental Sciences, Soil Physics, Ecohydrology, and Groundwater Management Group, Wageningen Univ., Nieuwe Kanaal 11, 6709 PA Wageningen, The Netherlands
^c Arid Land Research Center, Tottori Univ., 1390 Hamaska, Tottori 680, Japan
^* Corresponding author (ger.derooij{at}wur.nl)

Received 28 October 2004.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Fingered flow rapidly moves water and pollutants from the rootzone to the groundwater through a limited fraction of the unsaturatedzone, limiting the possibilities for decay and adsorption. Theonset of wetting front instability and the characteristics ofthe flow pattern under nonponding infiltration have receivedlimited attention. We aim to theoretically and experimentallyadvance our understanding of pre-fingered flow, and contrastfingered flow under ponding and nonponding conditions. We developeda Green-Ampt based expression for the pressure head in a developinginduction zone (from which fingers protrude) for the time beforefingers developed. A uniform, nonponding water flux was appliedto the surface of two-dimensional glass bead porous media witha dry region above a capillary fringe. Microtensiometers recordedpressure heads in the induction zone. The pressure head dataconfirmed both the theoretical early-time pre-finger model,and a model developed earlier for late-time lateral flow towardfully developed fingers. The physically more realistic constantflux boundary condition of our experiments gave larger fingerspacings and travel times, compared to the frequently used set-upwith ponding infiltration into a fine-over-coarse porous medium.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

UNSTABLE WETTING FRONTS produce fingers that rapidly removewater from the root zone and limit the soil's ability to neutralizeor adsorb contaminants before they reach the groundwater. Therefore,wetting front instability has been extensively researched (seethe reviews by Hillel, 1987; Glass and Nicholl, 1996; de Rooij, 2000;Hendrickx and Flury, 2001; Nieber, 2001). The physicalprinciples governing fingered flow have been studied mainlyby means of Hele-Shaw cells filled with idealized porous media(e.g., Hill and Parlange, 1972; Tamai et al., 1987; Diment and Watson, 1985;Glass et al., 1989, Baker and Hillel, 1990; Pendexter and Furbish, 1991;Wang et al., 1998, 2003).

At the onset of fingered flow, a few of usually many wettingfront protrusions extending from the induction zone gain dominanceand develop into full-grown fingers while the other protrusionscome to a virtual stand-still. The interplay between this fingerformation process and the pressure head dynamics in the inductionzone has received relatively little experimental attention,as most studies focused on the properties of the fingers themselves.Baker and Hillel (1990), Selker et al. (1992a), and Cho and de Rooij (1999)( 2002) used rapid-response tensiometers in Hele-Shawcells to observe pressure heads in the induction zone. Of those,only the latter had enough observation points in the inductionzone to study lateral flow toward the fingers in an inductionzone below a fine-over-coarse interface. Geiger and Durnford (2000)performed similar measurements in 12.7-mm diameter columns.

As indicated above, detailed lateral pressure head distributionsin the induction zone have only been observed in ponded fine-over-coarseprofiles. We therefore performed nonponding infiltration experimentswith two-dimensional glass bead porous media. We studied allstages of finger development and compared finger behavior withearlier ponded infiltration experiments (Cho and de Rooij, 2002).Flow inside the fingers was theoretically treated by Selker et al. (1992b),while de Rooij (1995) and de Rooij et al. (1996)theoretically analyzed finger dissipation in the capillary fringe.Theories for the onset of instability (see de Rooij's [2000]review) do not target details of the flow. This paper introducesa simple Green-Ampt type model for flow in the induction zoneunder constant, nonponding infiltration before finger formationto further develop the finger formation theory by Hillel and Baker (1988).

The objectives of this paper are (i) to develop the theory forprefingered flow; (ii) to verify experimentally the model-predictedpressure head evolution shortly after infiltration; (iii) tohighlight, theoretically and experimentally, some limitationsof the conventional set-up in which fingers are generated byponded infiltration through a poorly conductive layer into aninitially dry, coarse-grained medium; (iv) to expand and adaptthe findings of Cho and de Rooij (2002) for the early stagesof finger development under ponded infiltration. In addition,we provide a physical explanation of the bottle-neck shape offingers just above the capillary fringe, first reported by Liu et al. (1994).

THEORY

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Raats (1973) and Hillel and Baker (1988) hypothesized that awetting front penetrating a dry soil can only break up in distinctfingers if the downward water flux is insufficient to wet upthe entire horizontal cross-sectional area of the soil. If thehydraulic conductivity is continuous for – ${infty}$ < h <0 (where h is the pressure head, L), the soil can always adaptthe pressure head to make the entire horizontal cross-sectionparticipate in the flow. Including a water-entry pressure headh_we (L) effectively makes flow below this threshold impossible.In that case, fingers can form if the hydraulic conductivityat h_we exceeds the infiltration flux density. From Darcy's Lawit follows immediately that this corresponds to Philip's (1975)instability criterion, which stipulates that the pressure headgradient immediately behind the wetting front must oppose theflow. For coarse media, ${theta}$ (h_we) is close to saturation, and aGreen-Ampt type wetting front develops (see also Raats, 1973).Selker et al. (1992a)(1992b) and Cho and de Rooij (1999)(2002),among others, observed this type of wetting in the inductionzone from which fingers emerged in the course of their experiments.

Jury et al. (2003) suggested that a ${theta}$ -h relationship with a water-entrypressure head (below which the hydraulic conductivity duringinfiltration is zero) should allow Richards' equation to produceunstable wetting fronts. Egorov et al. (2003) conclude the samebut warn that such a modification fundamentally has no fastestgrowing perturbation of the wetting front, while experimentstypically show fairly uniform finger widths/radii. Based onEgorov et al.'s (2002) analysis they point to a nonequilibrium ${theta}$ -h relationship as a mathematically more acceptable requirementfor wetting front instability.

While the existence of a water-entry value during (near-) equilibriumconditions is physically realistic, h_we at equilibrium differsfrom that during infiltration (e.g., Geiger and Durnford, 2000).It is plausible that this dynamic nature of h_we is the way anonequilibrium ${theta}$ -h relationship manifests itself in tensiometerreadings.

Both the dynamic h_we and the nonequilibrium ${theta}$ -h relationshipare macroscopic representations of the pore-scale infiltrationprocess (see the observations of Lu et al., 1994a, 1994b). Bothof them allow Richards' equation to generate unstable wettingfronts. According to Egorov et al. (2003), the latter has theadvantage of being able to predict finger sizes.

In either case, flow in a drying soil should be stable. Filmflow along pore walls occurs for h << h_we (see Lu et al., 1994a,1994b), and the increased conductivity associated withuniformly wetted pore walls makes it likely that the memoryeffect in a nonequilibrium ${theta}$ -h relationship is much smaller duringdrying than during wetting. Therefore, equilibrium ${theta}$ -h relationshipswith a finite water-entry value as well as nonequilibrium ${theta}$ -hrelationships are likely to fulfill this requirement.

We analyze the flow in a developing induction zone by assumingGreen-Ampt infiltration (sharp wetting front, uniform volumetricwater content ${theta}$ behind the front) until the induction zone reachesa thickness that allows fingers to form. The wetting front pressurehead equals the dynamic water-entry value (dependent on theporous material and the flux density, see Geiger and Durnford, 2000).The nonponding, constant rainfall flux density is q₀(L T^–1), and starts at time t = 0. In the early stagesof infiltration (before finger formation), we have:

[1]
where K (L T^–1) is the unsaturated hydraulicconductivity, L (L) is the thickness of the induction zone (equalto the depth of the wetting front), and t (T) denotes time.The subscript 0 indicates the value is valid at the soil surface,the subscript "we" denotes a value corresponding to the waterentry pressure head. Note that fingers can only form if q₀ <K_we. The gradient of the hydraulic head (the bracketed termin Eq. [1]) will then lie between 0 and –1, and consequentlyh₀(t) can range from h_we to h_we – L(t).

Mass conservation dictates:

[2]
where ${theta}$ ₀ is the initial volumetric water content, assumed uniform (whichis reasonable in dry soils, even if h varies with depth).

With q₀ constant, the downward velocity of the wetting front(Eq. [2]) as well the gradient of the hydraulic head behindthe wetting front must necessarily be constant as well. IntegratingEq. [2] and combining the result with Eq. [1] leads to the followingexpression for the pressure head at the soil surface:

[3]
The pressure head at the soil surface increaseslinearly with time for stable flows (q₀ > K_we), decreases linearlywith time for unstable flows (q₀ < K_we), and remains constantwhen q₀ = K_we and unit gradient conditions prevail. It is importantto note that this behavior of h₀ under a nonponding constantflux upper boundary condition is fundamentally different fromthe poorly defined behavior of the pressure head at the texturalinterface of a fine-over-coarse profile that has often beenused to produce fingered flow under a constant ponding depth(e.g., Hill and Parlange, 1972, and many subsequent experiments).

The uniform volumetric water content ( ${theta}$ = ${theta}$ _we) behind the wettingfront leads to a pressure head profile of the form:

[4]
where z (L) denotes depth below thesoil surface and h(z,0) (L) is the initial, very low, pressurehead. As indicated above, h_we – L(t) $≤$ h₀(t) $≤$ h_we for unstableflows. Hence, in shallow induction zones, h will only vary afew centimeters. If h_we is located in the steep, wet-end rangeof the soil water characteristic, the water content will benearly uniform over the entire depth of the induction zone,validating the Green-Ampt approximation. With L(t) derived byintegrating Eq. [2] and h₀(t) according to Eq. [3], Eq. [4]gives the pressure head at any depth within the induction zone[0 < z < L(t)]:

[5]

Therefore, for unstable flows (q₀ < K_we), the pressure headanywhere in the induction zone decreases linearly with timeas the induction zone thickens, and increases with depth. Thelatter is consistent with Philip's (1975) instability criterionmentioned above. The pressure head at the soil surface cannotbe measured directly, but microtensiometers can be operatedat very small depths, allowing experimental verification ofEq. [5].

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

We performed nearly two-dimensional experiments in which a dyetracer visualized the flow pattern. The transparent, 1-cm-wideexperimental chamber with drainage outlets in the bottom andmicrotensiometer/air outlet ports in one of its walls was describedin detail by Cho and de Rooij (2002), who also described therapid-response microtensiometers and their operating procedures.We experimented with glass beads of 0.120 to 150 mm (Run 1)and 0.220 to 250 mm (Run 2), homogeneously packed accordingto Cho and de Rooij (2002) to create a layer of 68-cm thickness.Table 1 gives relevant properties of the porous packs, and Fig. 1gives the main drying and wetting curve of the fine material.The static water values for h_we were estimated from the heightof the capillary fringe. The dynamic values were obtained fromthe highest (least negative) tensiometer readings. Saturatedhydraulic conductivities were measured with a constant headpermeameter (Klute and Dirksen, 1986, p. 694–700).

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Table 1. Properties of the porous media used in the experiments.

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Fig. 1. The main wetting and drying curve of the 0.120- to 0.150-mm glass beads.

In both experiments, the chamber was placed in a water-filledreservoir with the water level at the same height as the chamberinner bottom. The water infiltrated through the drainage openingsand created a capillary fringe. After 11 d the chamber was takenfrom the reservoir. A horizontal array of tensiometers (5-cmspacing) was installed 1 cm below the soil surface, with a fewadditional tensiometers at various depths (see Fig. 2 and 3) ,including the capillary fringe. Pressure heads were recordedevery 10 s (Fig. 4) .

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Fig. 2. Front view of the experimental chamber with the wetting fronts observed at the indicated times for the run with the 0.120- to 0.150-mm glass beads. Tensiometers (labeled with characters) are indicated by solid green circles.

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Fig. 3. Front view of the experimental chamber with the wetting fronts observed at the indicated times for the run with the 0.220- to 0.250-mm glass beads. Tensiometers (labeled with characters and numbers) are indicated by solid green circles.

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Fig. 4. Experimental set-up. Before the water application started, the chamber containing the porous material was taken out of the water reservoir that helped create the capillary fringe.

A dye-solution (0.01 M KMnO₄) in distilled water was appliedto the porous medium surface by a low-flux rainfall simulatorconsisting of a nozzle oscillator and a micro-tubing pump (Fig. 4and 5) . Thirty-two nozzles (0.6-mm inner diam., 1.0-mm outerdiam., 45-mm length) were mounted 25-mm apart on a 90-cm-longplate that oscillated horizontally with 10-mm amplitude at afrequency that could be varied between 1.7 and 17 cycles min^–1.The micro-tubing pump (BVK MS/CA8-6, ISMATEC, Switzerland) hadfour blocks, with eight flow channels each. We fixed the applicationrate at 0.404 mm min^–1 for the fine material and 0.420mm min^–1 for the coarse material, in both cases providinga constant-flux upper boundary condition without ponding. Thewetting front advancement and finger development were videotapedand photographed (Fig. 4).

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Fig. 5. The rainfall simulator providing a constant, uniform flux density.

	RESULTS AND DISCUSSION

TOP ABSTRACT INTRODUCTION THEORY MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

Wetting Patterns
The run with the fine material produced a fairly flat wettingfront after the initial perturbations caused by the individualnozzles damped out within the first minutes (Fig. 2). Afterabout 75 min, three protrusions gained dominance over the otheroscillations. At that time, the wetting front had already advancedto approximately 6 cm. Only the right-most oscillation developedinto a finger. At the time the finger reached the capillaryfringe (110 min after the start of infiltration), the wettingfront halted at about 8-cm depth (excluding the protrusions).

Infiltration in the coarse material produced a more oscillatingwetting front, which generated a single dominant feature afterabout 45 min. The finger that developed from this reached thecapillary fringe after about 80 min. Again, the wetting frontstopped advancing at that time, reaching a depth of about 5cm.

Cho and de Rooij (2002) used the same glass beads in the sublayeras were used in our Run 1, but generated fingers by pondinga fine-over coarse profile. Their Run 1 involved a nearly flattextural interface, compatible with our flat soil surface. Sincetheir infiltration rate (0.373 mm min^–1) is comparableto ours, we can compare their Run 1 with ours. In our constantflux experiments, finger spacing was three times larger. Iflarger flow chambers had been used, the difference might havebeen larger since the fingers in both of our experiments appearednear a chamber wall. The induction zone under prescribed infiltrationwas considerably thicker (8 cm compared to 3 cm). The cumulativeinfiltration required to reach the capillary fringe increasedfrom 22.3 to 44.4 mm, even though the longer period of capillaryrise (11 instead of 6 d) resulted in a thicker capillary fringe.Since the prescribed flux upper boundary condition reportedhere better represents field conditions than the constant headboundary condition of ponded infiltration experiments, the lattermay underestimate solute residence times in the unsaturatedzone and overestimate the fraction of the horizontal cross-sectionwhich delivers water and solutes to the groundwater.

The fingers dissipated in the capillary fringe, consistent withearlier observations (Cho and de Rooij, 1999, 2002; de Rooij and Cho, 1999;de Rooij et al., 2001). But just before diverging,the fingers strongly converged in the few centimeters abovethe capillary fringe. Liu et al. (1994) first reported thisphenomenon in a prewetted layer, which was confirmed by theexperiments involving a capillary fringe referenced above. Itappears plausible that the smallest pores above the visiblecapillary fringe were wetted through capillary rise, therebyincreasing the hydraulic conductivity immediately above thecapillary fringe. If the wetting was such that the larger poresstill required a water-entry pressure head to be exceeded, fingerscould not dissipate in this region (the flow lines would notdiverge). The increased conductivity would allow a smaller cross-sectionof the porous medium to conduct the water flux carried by thefinger, thereby creating a region of convergent flow immediatelyabove the nearly saturated region of diverging flow. This explanationis supported by the experiments by Bauters et al. (2000), whonoted a reduced finger size when the porous medium was slightlywetted instead of air-dry.

Model Evaluation
The infiltration model represented by Eq. [5] predicts a lineardecrease of the pressure head within the induction zone beforefinger formation, consistent with Selker et al.'s (1992a)(1992b)early time observations. At the wetting front, the pressurehead equals the dynamic h_we. The rate of decrease is given by ${partial}$ h/ ${partial}$ t = q₀( ${theta}$ _we – ${theta}$ ₀)^–1[(q₀/K_we) – 1]. Assumingsaturation at the dynamic water entry value and ${theta}$ ₀ = 0, we calculated ${partial}$ h/ ${partial}$ t from independently measured saturated water contents ${theta}$ _s andhydraulic conductivities K_s (L T^–1) in Table 1. The timeat which the wetting front reached the tensiometers was calculatedby integrating Eq. [2]. Thus, the only parameter that was fittedto the observed h(t) curves was the dynamic value of h_we. Thedifference between the static and dynamic values of h_we (bothdetermined from observations) in Table 1 clearly illustratesthe unsuitability of the static value of h_we to predict pressureheads (and hence water contents and conductivities) prevailingbehind unstable wetting fronts and in fingers. Figures 6 and7 compare model results to observations for four representativetensiometers for both experiments. Even with the assumptionof saturation the model performed remarkably well.

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Fig. 6. Observed and modeled pressure head trends in the induction zone for the 0.120- to 0.150-mm porous medium. The numbers indicate the distance between the tensiometers and the left chamber wall. All tensiometers were installed at 1 cm below the soil surface. Vertical black lines mark the times at which the dominant finger became visible and reached the capillary fringe.

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Fig. 7. As Fig. 6, for the 0.220- to 0.250-mm porous medium.

We compared our model to pressure head observations during forcedone-dimensional infiltration in two silica sands and three sievefractions of one of those (Geiger and Durnford, 2000). We estimatedthe observed ${partial}$ h/ ${partial}$ t from the linear sections of the slopes of Geiger and Durnford's (2000)Fig. 2a and 2f, and calculated these slopesas outlined above using Geiger and Durnford's values of K_s andthe porosity to approximate K_we and ${theta}$ _we. The results (Table 2)show an excellent agreement between the observations and themodel for relatively large infiltration rates (0.2 K_s), exceptfor the fine sand (F-95) where the assumption of near-saturationat the dynamic h_we may have been invalid. For the coarse sand(F-14), the model performance for small flux rates was reasonable.

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Table 2. Comparison of ${partial}$ h/ ${partial}$ t predicted by Eq. [5] and observations by Geiger and Durnford (2000). The fractions in parentheses give the ratio of predicted over observed values. The labels identifying the sands refer to Geiger and Durnford (2000).

According to Eq. [5], the pressure head difference after passageof the wetting front between two vertically aligned points inthe induction zone equals [1 – (q₀/K_we)] ${Delta}$ z, where ${Delta}$ z (L)is the vertical distance between the points. We tested thisrelationship on tensiometer pair F and P ( ${Delta}$ z = 10.0 cm) in Fig. 2.For the period between the moment the wetting front passedtensiometer P and the moment the finger reached the capillaryfringe, the pressure head difference ranged without a cleartrend from 9.6 to 9.9 cm, averaging 9.7 cm. The pressure headdifference according to Eq. [5] should remain constant at 9.4cm (97% of the observed value) based on the porous medium propertiesin Table 1 and the infiltration rate.

Tensiometer Data
Figures 6 and 7 clearly show three phases in the pressure headbehavior related to the development of the wetting pattern.The first phase (development of the induction zone before fingerformation; fine medium: 0 to 75 min, coarse medium: 0–45min) confirms the linear pressure head decrease with time accordingto Eq. [5]. During the second phase (finger growth until thefinger tip reached the capillary fringe; fine medium: 75 to110 min, coarse medium: 45–80 min), relatively small pressurehead differences emerged, creating the lateral gradients neededto supply the growing finger with water. The differences increasedmore rapidly in the coarse medium, possibly because the decreasingpressure head resulted in air intrusion, which reduced the hydraulicconductivity. The third phase started when the fingers reachedthe capillary fringe. In the fine medium, the pressure headdropped within a few minutes, the differences increased (indicatingair intrusion), and the overall decreasing trend continued.In the coarse medium, the decreasing trend slowed down and reversedafter about 90 min, when the desaturation of the induction zoneand even the top of the finger could be visually confirmed (onlyin the coarse medium).

Figures 8 and 9 give the pressure head patterns in the inductionzone at the times for which the wetting fronts are given inFig. 2 and 3. Clearly, significant lateral pressure head gradientsonly developed after the fingers had firmly established themselves.The wetting pattern drove the pressure head pattern. This iscompletely opposite to the findings of Cho and de Rooij (2002)for ponded infiltration experiments, in which a sinusoidal pressurehead pattern developed within minutes, and fingers later formedat locations of pressure head minima.

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Fig. 8. Lateral pressure head distribution in the induction zone of the 0.120- to 0.150-mm porous medium at 1 cm below the soil surface. Numbers indicate the time in minutes since the start of infiltration. The widths of the main protrusions are indicated by the black lines. The right-hand-side protrusion developed into a finger. Solid lines indicate theoretical fits.

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Fig. 9. As Fig. 8, for the 0.220- to 0.250-mm porous medium. Dominant protrusions were absent, and only the finger is indicated by black lines.

The thick, nearly saturated induction zone is highly conductive.Consequently, the lateral flow toward the fingers required onlysmall lateral pressure head gradients, which allowed the largefinger spacing compared to the observations of Cho and de Rooij (2002)discussed above.

Modeling Lateral Flow
Cho and de Rooij (2002) developed a simple model for the pressurehead pattern in the induction zone after finger formation:

[6]
where x* (L) denotes the horizontal distance tothe nearest finger center, W (L) is the distance between thefinger center and its catchment's boundary, and C (L) is a constant.

The model assumes a uniform infiltration flux density and uniformand constant hydraulic conductivity and water content in theinduction zone and should therefore be applicable to the experimentsreported here. We identified the center of the fingers in bothexperiments to determine W for the left-hand side of the catchment.For each curve in Fig. 8 with t $≥$ 75 min, and for all curveswith t $≥$ 55 min in Fig. 9, we set C equal to the lowest readingsof one of the tensiometers adjacent to the finger center. ForK_we, L, and q₀ we used the values reported above. The calculatedlateral pressure head gradients were generally larger than thoseobserved for the fine porous medium. The mean absolute error(Nielsen and Wendroth, 2003, p. 152) between observed and calculatedpressure heads in the fine medium ranged from 14 to 18 cm forthe different times considered. The model performed much betterfor the coarse medium (mean absolute error between 0.78 and3.6 cm). We also determined LK_we and C by least-square fittingEq. [6] to the observed curves in Fig. 8 and 9. Since the curvatureclearly changed after 105 min (fine medium) and 70 min (coarsemedium), we allowed C to vary between curves (separate fits)to fit the height, but kept LK_we constant before and after thesetimes of curvature change to obtain two different shapes foreach experiment. The fits were excellent after the fingers hadreached the capillary fringe.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

In summary, we completed the work by Cho and de Rooij (2002)on flow and pressure head patterns in the induction zone byadding an analysis of the early-time behavior, before fingerformation. We also quantified the differences in the flow characteristicsemerging from a constant flux vs. a constant head upper boundarycondition (the latter for a fine-over-coarse porous medium):the former leads to larger finger spacings and travel timesto the capillary fringe than the latter. The model for lateralflow in the induction zone that Cho and de Rooij (2002) foundto be of limited use for constant head experiments performedvery well for a constant flux boundary condition after the fingersreached the capillary fringe.

ACKNOWLEDGMENTS

The first author thanks Dr. P. R. Berliner (Ben-Gurion Univ.,Israel) for his valuable suggestions.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

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Hill, D.E., and J.-Y. Parlange. 1972. Wetting front instability in layered soils. Soil Sci. Soc. Am. Proc. 36:697–702.

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Jury, W.A., Z. Wang, and A. Tuli. 2003. A conceptual model of unstable flow in unsaturated soil during redistribution. Available at www.vadosezonejournal.org. Vadose Zone J. 2:61–67.[Abstract/Free Full Text]

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