Hydraulic Conductivity, Immobile Water Content, and Exchange Coefficient in Three Soil Profiles

doi:10.2136/sssaj2005.0291

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Soil Physics

Hydraulic Conductivity, Immobile Water Content, and Exchange Coefficient in Three Soil Profiles

L. Alletto^a, Y. Coquet^b^,*, P. Vachier^b and C. Labat^b

^a Ecole Supérieure d'Agriculture de Purpan–75, voie du TOEC BP 57 611, 31 076 Toulouse Cedex 3, France
^b UMR INRA/INAPG Environment and Arable Crops, Institut National de la Recherche Agronomique/Institut National Agronomique Paris-Grignon, BP 01, 78 850 Thiverval-Grignon, France

^* Corresponding author (coquet{at}grignon.inra.fr)

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

We used tension disk infiltrometers to determine the hydraulicconductivity at the matric potential of –0.1 kPa (K_–0.1),the immobile water fraction ( ${theta}$ _im/ ${theta}$ ), and the mass exchange coefficient( ${alpha}$ ) in three soil profiles of an agricultural field cropped withwinter wheat (Triticum aestivum L.). A significant effect ofsoil horizonation was found for K_–0.1, ${theta}$ _im/ ${theta}$ , and ${alpha}$ and couldbe related to soil structure as determined either by tillagefor surface horizons or by pedogenetic factors for subsurfacehorizons. The seedbed had lower K_–0.1 values (31 to 99mm h^–1) than the plowed layer under the seedbed (94–430mm h^–1). The ${theta}$ _im/ ${theta}$ was highly variable in the seedbed (0.213to 0.882), while ${alpha}$ had values ranging from 0.0006 to 0.0115 h^–1.Values of ${theta}$ _im/ ${theta}$ and ${alpha}$ in the plow layer under the seedbed weresimilar but less variable than those found in the seedbed. Inthe subsoil, clay-enriched illuvial horizons had K_–0.1values similar to those found in the seedbed, but lower thanthose of the heavy clay horizon (average value of 260 mm h^–1)and the limestone horizons (average value of 450 mm h^–1).In the illuvial and heavy clay horizons, both ${theta}$ _im/ ${theta}$ and ${alpha}$ parametershad a small variability. In the limestone, we found a high variabilityof both ${theta}$ _im/ ${theta}$ values (0.506–0.933) and ${alpha}$ values (0.0006–0.0424h^–1) associated with high average values. The presenceof subsoil horizons with large ${theta}$ _im/ ${theta}$ and low ${alpha}$ values may havea significant impact on ground water contamination.

Abbreviations: DFBA, 2,6-diflurobenzoate • MIM, Mobile–Immobile Model • PFBA, pentafluorobenzoate • TFBA, trifluoromethylbenzoate

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

THE LARGEST AQUIFER in France is the limestone aquifer of theBeauce region with an estimated groundwater resource of nearly20 Mm³. The Beauce region is also one of the most intensiveagricultural areas in France. This intensive agriculture hasled to contamination of the Beauce groundwater by several pesticides(Institut Français de l'Environnement, 2004). Understandingthe mechanisms of groundwater recharge is essential to assesspollutant transfer to the water table. Many studies have shownthat water and solutes can move through soils according to differentkinds of preferential flow processes such as macropore flow,fingering, or nonequilibrium flow (van Genuchten and Wierenga, 1976;Thomas and Philips, 1979; Baker and Hillel, 1990; Brusseau et al., 1992;Jarvis, 1998). Using these preferential flow pathways, solutescan move rapidly below the biologically active root zone downto subsoil layers and the vadose zone, where degradation ratesare generally low (Mills et al., 2001; Wood et al., 2001).

To better describe field and laboratory observations, solutetransport models including physical nonequilibrium have beendeveloped. The Mobile–Immobile Model (MIM) considers thatthe water-filled pore space is partitioned into two domains:a mobile domain where water can move and solute transport isdue to advection and dispersion, and an immobile domain wherewater is stagnant and solutes move only by diffusion (Coats and Smith, 1964;van Genuchten and Wierenga, 1976). According to this concept,the one-dimensional transport of a nonsorbing conservative soluteunder steady-state water flow can be written

Formula 1 [1]
where ${theta}$ _m and ${theta}$ _im [L³ L^–3] are the mobileand immobile volumetric water contents, C_m and C_im [M L^–3]are the solute concentrations in the mobile and immobile domains,t [T] is time, D_m [L² T^–1] is the hydrodynamic dispersioncoefficient for the mobile domain, z [L] is depth, and q [LT^–1] is the water flux density. Exchange between the twodomains is described by the relation

Formula 2 [2]
where ${alpha}$ [T^–1] is the first-order massexchange coefficient between the mobile and immobile domains.

A field method to estimate ${theta}$ _im/ ${theta}$ and ${alpha}$ was proposed by Jaynes et al. (1995).The method uses a sequence of nonreactive conservative tracersapplied to the soil by using a tension infiltrometer under steady-statewater flow. Bromide and fluorobenzoates are commonly used tracers.They are considered to be conservative and inert, are easilyextracted and quantified from soil, and have a negligible backgroundin most soils (Bowman, 1984a, 1984b; Benson and Bowman, 1994;Kung et al., 2000a, 2000b; Flury and Wai, 2003).

This method has been applied to field conditions mainly on surfacesoil layers (Casey et al., 1997; Lee et al., 2000; Al-Jabri et al., 2002).References about MIM parameters in subsurface layers are scarce.Understanding the transport properties of solutes in subsoilhorizons is essential to describe solute behavior in the wholesoil profile and assess the groundwater pollution risks by contaminants.The objective of this study was to evaluate the MIM solute transportparameters and near-saturated hydraulic conductivity in thedifferent horizons from the surface down to the 1-m depth inthree soil profiles of an agricultural field. Statistical analysiswas used to detect horizonation effects on hydraulic and MIMparameters.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Field Site
The 25-ha field site is situated in the Beauce agriculturalregion, France. The field had been plowed to a depth of 28 cmin September 2003 and a 7-cm-deep seedbed was prepared beforewinter wheat (Triticum aestivum L.) was sown in November 2003.Field measurements of hydraulic conductivity and MIM parameterswere performed in the last week of April and the first 3 wkof May 2004.

A strong soil heterogeneity was found in the field. Accordingto the World Reference Base for Soil Resources (ISSS-ISRIC-FAO, 1998)the two main soil types are Orthic Luvisol and Eutric Cambisol.The substrate, which appeared at a variable depth, is a limestonehaving different levels of alteration.

Three 200-m² plots were selected to represent the main soiltypes encountered in the field. Plots 1 and 3 corresponded toOrthic Luvisols, and Plot 2 to a Eutric Cambisol. In each plot,excavations were dug to describe and sample the soil profile(Table 1). Samples were collected from the 28-cm-thick plowedorgano-mineral layer (LA1, LA2, and LA3) and from subsoil layers(BT1, BT3, B3, C1, C2, and C3) from each of the three plots.In Plots 1 and 3, BT1 and BT3 corresponded to clay-enrichedilluvial horizons and had similar soil characteristics. In Plot3, B3 corresponded to a heavy red clay horizon. Horizons C1,C2, and C3 corresponded to the weathered limestone. Each samplewas characterized by its particle size distribution (g kg^–1dry soil) after removal of the organic matter by H₂O₂ and decarbonationby HCl (Association Française de Normalisation, 1983),its organic C content (g kg^–1 dry soil) by sulfochromicoxidation (Association Française de Normalisation, 1999b),its pH in water, and its CaCO₃ content (g kg^–1 dry soil)by the volumetric method (Association Française de Normalisation, 1999a).

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Table 1. Characteristics of the surface (LA1, LA2, LA3) and subsurface soil horizons (BT1, C1, C2, BT3, B3, C3) of the three plots (1, 2, and 3).

Hydraulic Conductivity
We used tension disk infiltrometers to establish constant waterinfiltration rates at a soil water pressure of –0.1 kPa.For each soil horizon, we did two to four replicates locatedat 50 cm from each other horizontally. An 8-cm-diameter basewas used and contact between the disk and the soil surface wasensured by a fine, well-sorted Fontainebleau sand (Coquet et al., 2005).The cumulative infiltration, I (mm), could be expressed by atwo-term equation (Haverkamp et al., 1994; Vandervaere et al., 2000a):

Formula 3 [3]
where S( ${theta}$ _i, ${theta}$ _f) (mm h^–0.5)is sorptivity, ${theta}$ _i and ${theta}$ _f are initial and final volumetric watercontents respectively, A (mm h^–1) is a parameter describingthe effects of gravity and lateral absorption by soil on infiltration,and t is elapsed time (h). Hydraulic conductivity, K_–0.1(mm h^–1), could be obtained using the following equationfor parameter A (Haverkamp et al., 1994):

Formula 4 [4]
where ß is a constant in the interval(0, 1) taken as 0.6 (Vandervaere et al., 2000b), r is the radiusof the disk permeameter, and ${gamma}$ is a constant equal to 0.7 inmost soils. Derivatives of I vs. ${surd}$ t were used as a function of ${surd}$ t to calculate K_–0.1 as recommended by Vandervaere et al. (2000a).

Tracer Infiltrations
After water flow had reached steady-state infiltration, a sequenceof four anionic tracer solutions was applied at the same waterpressure (–0.1 kPa). The four tracers applied were Br^–,pentafluorobenzoate (PFBA), 2,6-diflurobenzoate (DFBA), andtrifluoromethylbenzoate (TFBA) at concentrations of 250 mg L^–1for Br^– and PFBA and 200 mg L^–1 for DFBA and TFBA.These high concentrations were necessary to limit the disturbancesproduced by a recent N application on the field. Two infiltrometerswere alternately filled with the four solutions. The first solutioncontained only Br^–. The second solution contained Br^–and PFBA, the third Br^–, PFBA, and DFBA, and the fourthsolution contained all the tracers. The time of applicationfor each tracer varied and depended on the infiltration rate.We did two to four replicate measurements for each soil horizon.After the penetration of the last solution, the infiltrometerwas removed and the contact material scraped off. Soil sampleswere taken beneath the center of the disk using a 25-mm-diameterstainless steel cylinder at 10-mm intervals down to 100 mm (inthe absence of coarse elements). Only the first centimeter underthe infiltrometer was used to determine ${theta}$ _im and ${alpha}$ . Other sampleswere used to established concentration profiles of each tracer.Samples were transported to the laboratory in hermetic jarsand stored at 4°C until analysis. The gravimetric watercontent was determined using a part of each sample and was usedto calculate the bulk density, ${rho}$ _b (g cm^–3), and the volumetricwater content of the whole sample based on its total wet mass.

Tracer Analysis
The soil was extracted using a 1:1 soil/deionized water ratio.Each sample was shaken for 24 h then centrifuged for 15 minat 9000g. The supernatant was filtered through a 0.45-µmnylon filter. Analysis of the fluorobenzoate tracers was doneusing a Waters HPLC Alliance chain equipped with a photodiodearray detector (Waters 996, Waters Corp., Milford, MA) withan anion exchange column (Platinum Sax 100A, 5u 250 mm by 4.6mm, Alltech France, Templemars, France). The mobile phase wasa KH₂PO₄ solution at 0.005 mol L^–1 with 20% of acetonitrileand a flow of 2 mL min^–1. The detection wavelength was205 nm. The pH was adjusted to 2.2 by adding H₃PO₄. Injectionvolume was 50 µL. The duration of the analysis was 15min. Under these conditions, retention times of TFBA, DFBA,PFBA, and Br^– were 2.9, 5.6, 9.2, and 12.5 min, respectively.In some samples, NO₃^–, with a retention time of 13.1 min,has perturbed the Br^– analysis. In these cases, Br^–ions were quantified using the same HPLC with another anionexchange column (A-2 Anion 7u 100 mm by 4.6 mm, Alltech). Theeluting solution was 2.2 mmol L^–1 Na₂CO₃ and 2.8 mmolL^–1 NaHCO₃ with a flow of 2 mL min^–1 and a detectionwavelength of 205 nm. Under these conditions, retention timesof Br^– and NO₃^– were 5 and 6.5 min, respectively(analysis duration: 10 min). Tracer concentrations in the infiltratingsolutions were also measured and checked for stability in timeand served as input concentrations C₀.

Immobile Water Content and First-Order Mass Exchange Coefficient
For each tracer, the mean resident solution concentration, C[M L^–3], is expressed by

Formula 5 [5]
where ${theta}$ [L³ L^–3] is the total volumetric water content:

Formula 6 [6]
Under the assumptions that theinitial tracer concentration in soil is zero and that the tracerconcentration in the mobile domain (C_m) is constant and equalto the injection concentration (C₀), which means that dispersionin the mobile domain does not affect C_m in the sampling volume, ${theta}$ _im and ${alpha}$ can be determined from

Formula 7 [7]
Theregression of ln(1 – C/C₀) vs. time should result in astraight line with the intercept ln( ${theta}$ _im/ ${theta}$ ) and the slope –( ${alpha}$ / ${theta}$ _im)(Jaynes et al., 1995). Snow (1999) has defined validity domainsfor the assumptions of this method. She showed that the qualityof ${theta}$ _im/ ${theta}$ and ${alpha}$ estimates was dependent on soil dispersivity, infiltrationrate, and the cumulative infiltration of tracers. Dispersivityvalues in the three profiles have been estimated from independentfield Br^–-tracing experiments and ranged between 1.5 and2.3 cm. We used large cumulative infiltrations for the lasttracer (TFBA) when facing high infiltration rates to ensurelimited errors on ${alpha}$ estimates as suggested by Snow's analysis.Although fluorobenzoates have a lower diffusion coefficientthan Br^– (Bowman, 1984b), it appears not to have affectedour results, because there was no systematic trend of Br^–-normalizedconcentration ln(1 – C/C₀) data points located below theregression lines. Such tracer effect seems to be negligiblein proportion to other experimental errors. Macropore flow couldalso have affected our MIM parameter measurements. FollowingNachabe (1995), the volumetric content of macropores ( ${theta}$ _mac) couldbe calculated from the water flux densities at –0.3 and–0.1 kPa. We did not have multipotential infiltrationmeasurements in the same three profiles but we used some dataobtained on similar soils in the same catchment (Coquet et al., 2005).The maximum ${theta}$ _mac value (0.0085) was found for a limestone C horizon.Correcting for macroporosity effect would result in the replacementof the left-hand side of Eq. [7] by ln(1 – C/C₀ – ${theta}$ _mac); however, such correction was found to be unnecessary because ${theta}$ _mac was always negligible in proportion to 1 – C/C₀, evenwhen ${theta}$ _im/ ${theta}$ was high.

Statistical Analysis
An unbalanced analysis of variance was done to study the effectof soil horizonation on the hydraulic and transport properties.Bonferroni tests were used to distinguish the soil horizonsthat had significantly different K_–0.1, ${theta}$ _im/ ${theta}$ , and ${alpha}$ values.We calculated the linear correlation coefficients between themeasured values of ${theta}$ , ${theta}$ _im/ ${theta}$ , ${alpha}$ , and q.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Hydraulic Conductivity
Surface Layer
Measurements were made at 3-cm depth in the surface layer (LA1,LA2, and LA3). Steady infiltration rates at –0.1 kPa wereachieved within $~$ 5 to 10 min and ranged from 15 to 139 mm h^–1(Table 2). Hydraulic conductivity at –0.1 kPa ranged from31 to 99 mm h^–1, with an arithmetic average and a medianfor all the surface layer measurements of 65 mm h^–1. Thesehydraulic conductivity values were close to previous resultsobtained for the seedbed of similar loamy soils (Coutadeur et al., 2002).Coefficients of variation of K_–0.1 were 36, 16, and 35%for LA1, LA2, and LA3, respectively. Cameira et al. (2003) foundsimilar CV values after disk plowing, but several studies indicatea CV of near-saturated conductivity >100% in plowed soilsdue to heterogeneity in macroporosity distribution (Reynolds et al., 1995;Coutadeur et al., 2002).

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Table 2. Water content ( ${theta}$ ), immobile water fraction ( ${theta}$ _im/ ${theta}$ ), mass exchange transfer coefficient ( ${alpha}$ ), hydraulic conductivity at –0.1 kPa (K_–0.1), steady-state infiltration rate (q), and cumulated infiltration (I), for the three soil profiles.

Observation of the tracer concentration profile in the surfaceLA experiments (Fig. 1) revealed a permanent jump between the6- and 8-cm depths (3- and 5-cm relative depths). This discontinuitycorresponds to the depth of the superficial tillage that hadbeen done after plowing for the preparation of the seedbed andmarks the separation between the seedbed (0–7 cm) andthe underlying undisturbed plow layer (7–28 cm). We madecomplementary measurements at 8-cm depth in Plot 2 (called LA2bin Table 2). A higher mean K_–0.1 value (263 mm h^–1)than in the seedbed was obtained, but also a higher variabilitybetween replicates (CV >90%). The low K_–0.1 valuesand low K_–0.1 variability in the seedbed compared withthe underlying plowed layer suggests that the rotary harrowtillage used for seedbed preparation has disrupted macroporecontinuity and homogenized the upper part of the plowed horizon.

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Fig. 1. Resident concentration of the four anionic tracers (Br^–, pentafluorobenzoate [PFBA], 2,6-diflurobenzoate [DFBA], and trifluoromethylbenzoate [TFBA]) at the end of experiment in surface layers (a) LA1, (b) LA2, and (c) LA3. Depth is relative to the infiltration surface, which was located 3 cm below the actual soil surface.

Subsurface Horizons
Among the subsurface horizons, the clay-enriched illuvial horizonssubjacent to the plowed horizon of Plots 1 (BT1) and 3 (BT3)had similar soil characteristics (Table 1). Values of K_–0.1ranged from 28 to 85 mm h^–1 (Table 2) with CVs of 43 and18% for BT1 and BT3, respectively. These horizons were not affectedby tillage and that could explain their low K_–0.1 variability.Morphological description of these horizons indicated that clayilluviation formed coatings around peds that had a partiallycompact and subangular structure. Intraaggregate sorption andinteraggregate flow may have been limited because of clay illuviation.The K_–0.1 values found in BT1 and BT3 horizons may bethe result of both clay accumulation and the absence of disturbanceby tillage. Bejat et al. (2000) observed a similar trend fora surface horizon with a decrease in saturated hydraulic conductivitywhen clay content increased and intensity of tillage practiceswas reduced. Heuvelman and McInnes (1997) found the highestwater flow rate variability in a BT horizon, but their BT horizonpresented well-structured prismatic aggregates.

In the heavy clay horizon, B3, the mean K_–0.1 value was258 mm h^–1 with a CV of 13%. We observed that this horizonhad no sign of clay illuviation (no coatings) and had largeprismatic aggregates (>20 cm) between which water could easilyrun. In the particular case of prismatic aggregates, it hasbeen shown that, depending on initial water content, the hydraulicconductivity could be higher than for other types of structure(Bouma and Anderson, 1977; Lin et al., 1998). An important macroporositydue to biological activity was also clearly visible. Despitea texture that would have indicated a low hydraulic conductivity,this horizon had one of the highest conductivities measuredin the three soil profiles (Table 2). Several studies have shownthat clayey soils with biopores or cracks, such as the one weobserved, could have higher hydraulic conductivity values thancoarse-textured soils (Bouma, 1991; Lin et al., 1997, 1998,1999).

At the base of the soil profiles, the limestone substrates hadthe highest K_–0.1 values that ranged between 114 and 852mm h^–1, with a global arithmetic mean for the three plotsof 446 mm h^–1. Coefficients of variation were 37, 54,and 39% for C1, C2, and C3, respectively. These substrates correspondto different facies of the Beauce limestone. These limestoneshave a high capacity to conduct water because they are denselyfractured or have a high water-conducting porosity that hasbeen created by chemical and mechanical weathering. Their faciesalso presented a high spatial variability within our experimentalfield.

Solute Transport Properties
Surface Layer
Tracer concentration data vs. time were correctly describedby Eq. [7] with an average R² of 0.82 (Fig. 2). Values of ${theta}$ _im/ ${theta}$ ranged from 0.213 in LA1 to 0.882 in LA3 (Table 2), with a globalarithmetic mean value of 0.533, a median of 0.482, and a CVof 52% (Fig. 3). Values of ${alpha}$ ranged from 0.0006 h^–1 inLA1 to 0.0115 h^–1 in LA2 (Table 2), with a global arithmeticmean value of 0.0031 h^–1, a median of 0.0017 h^–1,and a CV of 130%. Casey et al. (1998) found ${theta}$ _im/ ${theta}$ to range from0.28 to 0.95 and ${alpha}$ to range from 0.015 to 0.3 h^–1, Al-Jabri et al. (2002)found ${theta}$ _im/ ${theta}$ to range from 0.36 to 0.88 and ${alpha}$ to range from 0.002to 0.12 h^–1, and Ilsemann et al. (2002) found ${theta}$ _im/ ${theta}$ to rangefrom 0.11 to 0.27 and ${alpha}$ to range from 0.015 to 0.034 h^–1,all for the same soil type (Nicollet loam) but with differenttechniques. Ilsemann et al. (2002) also found ${theta}$ _im/ ${theta}$ values between0.04 and 0.07 and ${alpha}$ values between 0.001 and 0.008 h^–1for a fine-loamy to medium sand. Kookana et al. (1993) measured ${alpha}$ values between 0.008 and 0.6 h^–1 for various flow ratesin sand columns. Our results for ${theta}$ _im/ ${theta}$ were similar to these studies,but ${alpha}$ values were rather small (except one measure in LA2). The ${alpha}$ values that we measured in the surface layer correspond tocharacteristic diffusion times, t_c = ln2/ ${alpha}$ , between the mobileand immobile domains of 2.5 to 49 d. Such slow exchange ratesbetween the mobile and the immobile water domains suggests thatsingle-tracer techniques (Clothier et al., 1992, 1995) couldbe used to simply assess ${theta}$ _im/ ${theta}$ in these soils. Another importantconsequence is that earlier breakthrough of solutes may be expectedwhen ${theta}$ _im/ ${theta}$ is large and ${alpha}$ is small, as in the case of the LA3 horizon,than if preferential flow didn't exist and all the soil watercontributed to solute transport.

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Fig. 2. Normalized resident concentrations (C is the mean resident solution concentration and C₀ is the input concentration) of each tracer vs. application time for all experiments. In each graph, points with the same symbol correspond to the same experiment (four tracers). Linear regression lines are shown for each experiment.

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Fig. 3. Mass exchange coefficient values ( ${alpha}$ ) and immobile water fraction ( ${theta}$ _im/ ${theta}$ ) as a function of depth in (a and b) Plot 1, (c and d) Plot 2, and (e and f) Plot 3. Measured values are shown as open circles and error bars represent 95% confidence limits of the mean values.

Despite a relatively low variability of the hydraulic conductivityin the seedbed, the amplitude of variation of ${theta}$ _im/ ${theta}$ was high,especially in LA3 (Fig. 3). This variability might be due toa small-scale variability of soil structure, which greatly influencesthe characteristics of the transport processes (Casey et al., 1997;Okom et al., 2000).

We looked at the potential impact of the rotary harrow tillage(done before sowing) on MIM parameters and made measurementsat the 8-cm depth in the LA2 horizon (LA2b samples). AlthoughK_–0.1 values were different from the upper part of thehorizon, we obtained similar but less variable values of ${theta}$ _im/ ${theta}$ and ${alpha}$ (Table 2). These differences in MIM parameters are probablyrelated to differences in soil structure. High variability of ${theta}$ _im/ ${theta}$ and ${alpha}$ values in the seedbed may be due to a larger numberof pore discontinuities created by superficial tillage thanin the older, partially settled, plowed layer.

In surface horizons (Table 3), we found positive correlationsbetween ${alpha}$ and the steady-state infiltration rate q at the 0.01level as observed by Kookana et al. (1993) and Casey et al. (1997).

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Table 3. Pearson linear correlation coefficients between water content ( ${theta}$ ), immobile water content ( ${theta}$ _im), immobile water fraction ( ${theta}$ _im/ ${theta}$ ), mass exchange transfer coefficient ( ${alpha}$ ), and steady-state infiltration rate at –0.1 kPa (q), for the various horizons of the three soil profiles.

Subsurface Horizons
As for surface horizons, tracer concentrations could be describedadequately by Eq. [7] (Fig. 2) with an average R² of 0.78. Inthe clay-enriched illuvial horizons, BT1 and BT3, ${theta}$ _im/ ${theta}$ valuesranged from 0.350 to 0.521 and ${alpha}$ ranged from 0.0007 to 0.0027h^–1, corresponding to characteristic diffusion times between11 and 41 d. The low variability between replicates for ${theta}$ _im/ ${theta}$ (CV = 43% for BT1 and CV = 18% for BT3) might be due to thehomogeneity of the media. These horizons were massive, withcompact and subangular aggregates joined by coatings.

For the heavy clay horizon, B3, the arithmetic mean ${theta}$ _im/ ${theta}$ valuewas 0.304 with a 0.263 to 0.356 range and ${alpha}$ values ranged from0.0009 to 0.0016 h^–1 (characteristic diffusion times of18–32 d) with an arithmetic mean value of 0.0012 h^–1.Significant positive correlations were found between ${theta}$ and ${theta}$ _imas well as ${theta}$ and ${alpha}$ , and a negative correlation was found between ${theta}$ and ${theta}$ _im/ ${theta}$ (Table 3). The heavy clay B3 horizon had ${theta}$ _im/ ${theta}$ valuesclose to those of the BT3 horizon, and ${alpha}$ values similar to thoseof the BT1 horizon (Fig. 3). According to the literature, theimmobile water fraction increases with clay content (Lee et al., 2000;Okom et al., 2000; Kjaergaard et al., 2004) and aggregate size(Rao et al., 1980; Nkedi-Kizza et al., 1983, 1984). In the heavyclay horizon with a coarse prismatic structure, we thus expectedhigher values of the immobile water fraction than in the otherhorizons but instead we found values to be among the lowest(Fig. 2). In this clay horizon, morphological description ofthe prismatic aggregates showed that the number of biologicalmacro- and mesopores (>100 µm) was important. The highhydraulic conductivity at –0.1 kPa in this horizon suggeststhat these biopores were well interconnected, as observed inseveral clay soils by Lin et al. (1996, 1997), thus limitingdead-end pores and stagnant intraaggregate water.

In the limestone materials, ${theta}$ _im/ ${theta}$ values were very high and rangedfrom 0.506 to 0.933 (CV = 20%) with ${alpha}$ values between 0.0006 and0.0424 h^–1 (CV = 87%), corresponding to characteristicdiffusion times ranging from 0.7 to 48 d (Table 2). These valuesof ${alpha}$ were higher and more variable than those of the other horizons(Fig. 3). The limestone horizons had a granular structure withsmall peds, resulting in large exchange surfaces. Diffusionmay be enhanced and could explain high ${alpha}$ values. The high variabilityin ${theta}$ _im/ ${theta}$ values prevented us from finding any relation with thecomposition or structure variability of these horizons. We foundsignificant correlations between ${theta}$ and ${theta}$ _im and between ${theta}$ and ${alpha}$ ,as for the heavy clay B3 horizon. We also found in these horizonsa significant correlation between ${alpha}$ and q (Table 3).

The correlation analysis based on all the transport parametervalues of all horizons showed a positive correlation at the0.01 probability level between ${theta}$ _im and ${theta}$ (Fig. 4a), ${theta}$ _im and ${alpha}$ , ${theta}$ _im/ ${theta}$ and ${alpha}$ , ${theta}$ _im/ ${theta}$ and q, and ${alpha}$ and q (Table 3). Other studies reportedpositive correlation between ${alpha}$ and ${theta}$ _im (Skopp et al., 1981; Casey et al., 1997;Lee et al., 2000, Al-Jabri et al., 2002), which could be explainedby the mechanical diffusion model. When the regions of contactbetween the mobile and the immobile domains expand, as the immobiledomain increases, exchanges between the two domains become fasterand so ${alpha}$ increases. We found a significant relation between log( ${alpha}$ )and log(v) where v is the average pore water velocity. UnlikeCasey et al. (1997), our data did not fit Kookana et al. (1993)'sregression line (Fig. 4b). This is because the ${alpha}$ values thatwe measured in our soils were more than one order of magnitudelower than those reported by Kookana et al. (1993) in the samerange of pore water velocities. Such difference is probablyrelated to the type of soils considered in this study. Mostof the soils considered by Kookana et al. (1993) were sandyor well-aggregated soils. In our study, the soils have texturesdominated by the silt and clay fractions (Table 1) and tendto have coarse structures (BT and B horizons) and verticallyoriented tubular pores. We also found a negative correlationat the 0.01 probability level between ${theta}$ _im/ ${theta}$ and ${theta}$ and between ${theta}$ and q.

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Fig. 4. Relationships between (a) the immobile volumetric water content and the total volumetric water content and (b) the logarithm of the mass exchange coefficient ( ${alpha}$ , h^–1) and the logarithm of the average pore water velocity (v, cm h^–1).

Statistical Analysis
We analyzed the entire K_–0.1, ${theta}$ _im/ ${theta}$ , and ${alpha}$ data using ANOVAto study the effect of soil horizonation on these hydraulicand transport properties. We found a significant effect of soilhorizonation on K_–0.1 at a probability level of 0.001,but also on ${theta}$ _im/ ${theta}$ at a probability level of 0.001 and ${alpha}$ at a probabilitylevel of 0.02. We used a Bonferroni test to group the differenthorizons with similar K_–0.1, ${theta}$ _im/ ${theta}$ , or ${alpha}$ values. For theK_–0.1 values, we found a significant difference betweenthe C1 horizon and the seedbed (LA1, LA2, and LA3) and illuvial(BT1 and BT3) horizons. The C1 horizon had a mean K_–0.1one order of magnitude larger than the seedbed and BT horizons.These results are consistent with those of Coquet et al. (2005),who found the same differentiation in the same type of soilsbetween the tilled layer, having a low near-saturated hydraulicconductivity, and the limestone substrate (C horizon), havinga high near-saturated hydraulic conductivity, with B horizonshaving intermediate K values. Our results support the observationthat pedological organization and tillage practices can resultin hydraulic conductivity differentiation within agriculturalsoil profiles.

The C1 and C3 limestone horizons had ${theta}$ _im/ ${theta}$ mean values >0.75—significantlydifferent from the LA1, BT3, and B3 horizons, which had ${theta}$ _im/ ${theta}$ values <0.40. No horizon could be differentiated from theother from the point of view of their ${alpha}$ parameter values by theBonferroni test at the 0.05 level. Our results show that differentsoil horizons can have different MIM parameters. In our study,limestone C horizons had large MIM parameter values comparedwith the rest of the soil. This highlights the importance ofthe vadose zone, where significant MIM preferential flow mayoccur. Preferential flow can seriously modify initial estimatesof groundwater contamination based on the application of theclassical convection–dispersion equation to vadose zonetransport.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

We used the Jaynes et al. (1995) method to study hydraulic andtransport properties of several materials from the surface downto the 1-m depth in a heterogeneous field of the Beauce regionin France. Results show that the mobile–immobile typeof preferential transport was indeed a characteristic of Beaucesoils. By using only a part of the total porosity, qualifiedas "hydraulically active," solutes can move within the soilprofile at a higher rate than if all the porosity was active.

Tillage had a large influence on the hydraulic conductivityat –0.1 kPa of surface horizons. A high variability insolute transport properties was recorded and seemed to be dependenton the structure created by tillage. In particular, the seedbed,with highly erratic immobile water fractions and low ${alpha}$ values,was different from the underlying plowed layer that had lessvariable ${theta}$ _im/ ${theta}$ and ${alpha}$ values. In subsurface horizons, an immobilewater fraction was also detected. The occurrence of an immobilewater fraction was not correlated with clay content but seemedto be more dependent on soil structure. In limestone materials,large immobile water fractions were found, and ${alpha}$ values werelarger than for the upper horizons. We did not find any cleargeneral relationship between MIM parameters and soil properties,but it appeared, as suggested by Heuvelman and McInnes (1999),that the interplay of several soil characteristics, such astexture, structure, and pore geometry, greatly influence theoccurrence of preferential transport. To better describe groundwatercontamination risks, MIM parameters not only of the surfacebut also of the subsurface soil layers should be used in models.

ACKNOWLEDGMENTS

We wish to thank Nathalie Bernet and Véronique Etiévantfor their help in laboratory analysis. This work was financiallysupported by the Ministry of Ecology and Sustainable Developmentof France.

Received for publication September 5, 2005.

REFERENCES

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