Soil Wetting and Texture Effects on Aggregate Stability, Seal Formation, and Erosion

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Division S-6—Soil & Water Management & Conservation

Soil Wetting and Texture Effects on Aggregate Stability, Seal Formation, and Erosion

M. Lado^*, M. Ben-Hur and I. Shainberg

Institute of Soil, Water and Environmental Sciences, the Volcani Centre, Agricultural Research Organization, P.O. Box 6, Bet Dagan, 50250, Israel

^* Corresponding author (marcos{at}volcani.agri.gov.il)

ABSTRACT

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

Previous studies about the effect of antecedent moisture content(AMC) on seal formation have shown contradictory results. Wehypothesize that this controversy is related to differencesin slaking during wetting. The objectives were to analyze theeffects of: (i) clay content on aggregate stability and slaking;(ii) clay content and slaking on seal formation and interrillerosion under various wetting rates (WR) and AMC under simulatedrain. Aggregate stability was determined on six smectitic soilsfrom Israel with clay content from 80 to 630 g kg^–1. Inthe rain simulator, soils with 230, 410 and 620 g kg^–1clay were prewetted with WR = 1 and 5 mm h^–1 to AMC =0.25 and 0.5 of field capacity (FC), prior to the applicationof 80 mm of rain. Aggregate stability and slaking by fast WRincreased with increase in clay content. In soils with 230 and410 g kg^–1 clay, raindrop impact was enough to disintegratethe aggregates and sealing was not affected by WR and AMC. Conversely,in the soil with 620 g kg^–1 clay, seal formation increasedwith slaking caused by fast wetting. Thus, final infiltrationrate of the clay soil with AMC = 0.5 FC and WR = 1 mm h^–1was 11.1 mm h^–1 compared with 6.0 mm h^–1 in theair-dry soil (fast wetting by rain). The effects of WR and AMCon soil loss were similar to their effect on runoff but morepronounced. The relation between wetting process and clay contentshould be considered when predicting soil erosion in smectiticsoils.

Abbreviations: AMC, antecedent moisture content • FC, field capacity • IR, infiltration rate • WR, wetting rate

INTRODUCTION

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

RUNOFF AND SOIL EROSION are widespread land degradation problemsin many parts of the world. The formation of a surface sealis the main process responsible for IR reduction, runoff generation,and soil loss (Morin et al., 1981). A seal consists of two distinctparts: an upper skin attributed to compaction by raindrop impact,and a "washed-in" zone of decreased porosity, attributed tothe accumulation of small particles (McIntyre, 1958). Agassi et al. (1981)suggested that formation of a structural sealis a result of two complementary mechanisms: (i) a physicaldisintegration of surface soil aggregates, caused by wettingand raindrop impact energy; and (ii) the physicochemical dispersionof clay particles, which migrate into the soil with the infiltratingwater, and clog the pores immediately beneath the surface toform the "washed-in" zone.

Raindrop kinetic energy effects on seal formation, IR, and soilloss have been studied extensively (e.g., Mohammed and Kohl, 1987;Agassi et al., 1994). Agassi et al. (1985) showed thatwhen soil was exposed to drops with kinetic energy <0.01J mm^–1 m^–2, a seal was not formed. However, whenthe kinetic energy was 23 J mm^–1 m^–2, a seal witha very low hydraulic conductivity was formed. Al-Durrah and Bradford (1982a)( 1982b) studying several soils and falling heightsand three sizes of drops, concluded that splash erosion wascorrelated with raindrop kinetic energy and inversely proportionalto soil shear strength. Shainberg et al. (2003) suggested thatthe raindrop impact energy plays a dominant role in seal formationonly in sandy loams to silt clays (soils with <300 g kg^–1clay). In clay soils with stable structure fast wetting wasessential for seal formation and raindrop impact played a secondaryrole. The physicochemical mechanism in seal formation is controlledmainly by cations concentration and composition in the soiland applied water (Agassi et al., 1981; Kazman et al., 1983).The role of this mechanism in seal formation has been studiedin detail and can be predicted satisfactorily from basic mineralogicaland chemical properties of the soil (Shainberg and Letey, 1984;Stern et al., 1991).

Aggregate disintegration caused by fast wetting (slaking) iswell documented (Le Bissonnais and Arrouays, 1997; Abu-Sharar et al., 1987;Loch, 1994; Lado et al., 2004). Slaking occurswhen the aggregate is exposed to stresses produced by differentialswelling, entrapped air explosion, rapid release of heat duringwetting, and the mechanical action of moving water (Emerson, 1977;Kay and Angers, 1999). Slaking is determined by the WRof the soil; the faster the WR the higher the slaking forces(Le Bissonnais and Arrouays, 1997). Aggregate slaking is essentialto seal formation in soils with high clay content and high aggregatestability (Loch, 1994; Shainberg et al., 2003).

The effect of soil WR on aggregate stability, seal properties,and soil erosion depends on the AMC of the soil. Fast wettingof a moist soil causes less slaking compared with fast wettingof a dry soil. Also, the method by which soil AMC was maintainedis important. Fast wetting of a dry soil to a given AMC maydisintegrate the aggregates before exposing the soil to a rainstorm.Consequently, studies on the effect of WR and AMC on seal formationlead to contradicting results (e.g., Wischmeier and Mannering, 1969;Luk, 1985; Truman and Bradford, 1990; Truman et al., 1990;Le Bissonnais and Singer, 1992; Reichert and Norton 1994). Forexample, Luk (1985) reported that increasing AMC from near wiltingpoint to saturation produced a five-fold increase in soil lossin two silt loam soils. Reichert and Norton (1994) reportedthat wetting the soil for 2 h at –0.5 kPa tensions beforethe rain, generally increased or had little or no effect onrunoff and soil loss in most soils except for a stable Oxisolfor which wetting decreased soil loss. Truman and Bradford (1990)found that for four out of five soils studied, prewetting thesoil for 48 h reduced significantly splash and wash erosioncompared with air-dried soil. Le Bissonnais and Singer (1992)analyzed runoff and soil loss generated in two soils with 298and 417 g kg^–1 clay under two initial conditions: air-dryand 24 h prewetted by capillary action, and found that increasingAMC reduced runoff and soil loss.

Recently, Levy et al. (1997) prewetted two soils, a silt loamand a sandy clay, with 5 mm of deionized water and WR of 1 and30 mm h^–1. Thereafter, the soils were exposed to rainfallof approximately 32 mm h^–1. A decrease in WR from 30 to1 mm h^–1 decreased the total runoff and soil loss in bothsoils (Levy et al., 1997). Mamedov et al. (2001)(2002) showedthat when prewetting the soil until saturation, the effect ofWR (2, 8, and 64 mm h^–1) on runoff and interrill erosiondepends on clay content of the soil. The effect of WR was pronouncedin clay soils, negligible in sandy loam and silt loam, and moderatein soils with intermediate clay content. Similarly, the effectof AMC on seal formation and soil loss could be influenced byWR, and the contradicting results found by many authors couldbe due to the use of soils with different properties (e.g.,clay content) and WRs before the application of rain.

Clay can act as a cementing material that holds particles togetherin the aggregate (Emerson, 1977). Therefore, increasing theclay content in the soil increases aggregate stability (Kemper and Koch, 1966;Boix-Fayos et al., 2001). Ben-Hur et al. (1985),studying the effect of clay content on the susceptibility ofsoils to seal formation and soil loss, found that in soils withlow clay content (<100 g kg^–1), IR was high and runoffwas low because the amount of clay in the soil was not enoughto clog the pores and form a seal. In soils with clay content>300 to 400 g kg^–1 the rate of seal formation was low,because the clay acted as a cementing material that increasedaggregate stability and diminished seal formation (Ben-Hur et al., 1985).Consequently, high IR and low runoff were observedin clay soils. Soils with intermediate clay content (200 g kg^–1)were the most susceptible to seal formation because the amountof clay was too low to stabilize the aggregates, but was enoughto clog the pores at the soil surface (Ben-Hur et al., 1985).

An increase in clay content in the soil could also increaseslaking forces during soil wetting. Under fast wetting, an increasein clay content in the aggregate also increase the extent ofdifferential swelling and the volume of entrapped air that,in turn, increase aggregate slaking. Therefore, an increasein clay content in the soil might have two opposing effectson seal formation: (i) an increase in aggregate stability anddiminishing seal formation and (ii) an increase in aggregateslaking, on wetting, and an increase in soil susceptibilityto sealing. Thus, the objectives of this study were: (i) todetermine the effects of clay content on aggregate strengthand on aggregate slaking; (ii) to study the effects of WR, AMC,and clay content on seal formation, IR, and interrill erosion.

MATERIALS AND METHODS

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NOTES
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Soil Samples
Soil samples were taken from the surface (0.05–0.25 m)of six cultivated soils in Israel. The soils properties weredetermined by Mamedov et al. (2002) using standard analyticalmethods (Klute, 1986; Page et al., 1986). Some physical andchemical properties of these soils are presented in Table 1.Clay contents in the soils ranged between 80 and 620 g kg^–1.All the soils had similar mineralogy with smectite as the dominantclay, and the exchangeable sodium percentage levels were relativelylow (Table 1).

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Table 1. Particle-size distribution, CaCO₃ content, organic matter content (OM), cation exchange capacity (CEC), and exchangeable sodium percentage (ESP) of the studied soils.

The soil samples were air-dried, visible roots, and organicresidues were removed, and the air-dry samples were crushedand sieved. Samples of the soils were subjected to the followingstudies.

Aggregate Stability Study
The aggregate stability of the six soils was determined by twomethods: (i) Fast-wetting in water as proposed by Le Bissonnais (1996)and (ii) Slow wetting (1 mm h^–1) by mist.

(i) Fast Wetting.
Samples of aggregates 3 to 5 mm in size were put in the ovenat 40°C for 24 h, and 5 g of the oven-dry aggregates wereimmersed in a beaker containing 50 cm³ of deionized water (fastwetting). Following saturation for 10 min the water was suckedoff with a pipette. The soil material was transferred to a 50-µmsieve that had previously been immersed in ethanol and gentlymoved up and down in ethanol five times to separate <50-µmfragments from >50-µm ones. The >50-µm fractionwas oven dried and then gently dry sieved by hand on a columnof sieves of mesh sizes 2, 1, 0.5, 0.25, 0.1, and 0.05 mm. Theweight of each fraction was measured; and that of the <50-µmfraction was calculated as the difference between the initialweight and the sum of the weights of the other six fractions.

(ii) Slow Wetting.
Samples of aggregates 3 to 5 mm in size were wetted with 1 mmh^–1 mist to saturation. A detailed description of thewetting methods is presented in the rain simulation section.Following wetting, the aggregates were transferred to a 50-µmsieve immersed in ethanol, and the same sieving procedure asdescribed in the fast wetting test was used.

The aggregate stability for each soil sample in the two methodswas expressed by calculating the mean weight diameter (MWD)of the seven classes:

[1]
where w_i isthe weight fraction of aggregates in the size class i with adiameter _i. The higher the MWD was the higherthe aggregate stability (Le Bissonnais, 1996).

Rainfall Simulator Study
This study was conducted with three cultivated soils: A loamwith 230 g kg^–1 clay from Nevatim, a clay soil with 410g kg^–1 clay from Hafetz Haim, and clay soil with 620 gkg^–1 clay from Eilon (Table 1). The reported values ofmoisture contents of the three soils at FC were 200, 343, and480 g kg^–1 by weight, respectively (Koyumdjisky and Soriano, 1988).

The IR, runoff, and soil loss from the three soils were determinedby means of a rotary disc rainfall simulator (Morin et al., 1967).The typical mechanical parameters of the simulated rainfallwere: rainfall intensity, 42 mm h^–1; raindrop mean diameter,1.9 mm; median drop velocity, 6.2 m s^–1; and kinetic energy,18.1 J mm^–1 m^–2.

The air-dry soils were crushed and sieved to obtain sampleswith aggregate size <4 mm. The samples were packed in perforatedtrays measuring 0.30 by 0.50 m and 0.02 m deep. The packed soiltrays were placed on an 8-cm thick layer of coarse sand, ina box positioned under the rainfall simulator at a slope of9%. The bulk densities in the trays of the soils with 230, 410,and 620 g kg^–1 clay were 1.2, 1.15, and 1.1 Mg m^–3,respectively.

The soil samples were prewetted from the top with deionizedwater applied as mist. With this procedure, the mechanical breakdownof the aggregates by the raindrop impact was prevented. Threelevels of mist depths were applied to obtain three average levelsof AMC: air-dry, 0.25, and 0.5 of the FC. To obtain these AMClevels, the depths of mist applied to the soil with 230 g kg^–1clay were 0, 1.2, and 2.4 mm, respectively; to the soil with410 g kg^–1 clay, 0, 1.95, and 3.9 mm, respectively; andto the soil with 620 g kg^–1 clay, the depths of mist appliedwere 0, 2.7, and 5.4 mm, respectively. It is expected that theupper layer of the soil in the tray will be wetter than thelower layer in each AMC level, and that the AMC levels of 0.25and 0.5 of the FC are only average values for the entire soildepth. Nevertheless, the water content of the upper 2 mm ofthe soil surface at AMC of 0.5 FC was higher than at AMC of0.25 FC.

For each AMC, wetting of the soils with mist was done with twoWRs, 1 and 5 mm h^–1. The WR of 1 mm h^–1 was obtainedby exposing the soil trays to 6 s of 30 mm h^–1 mist inevery 3-min cycle. The WR of 5 mm h^–1 consisted of applying30 mm h^–1 mist for 30 s in 3 min cycle. The prewettingduration varied between 0.24 h in the soil with 230 g kg^–1clay with AMC of 0.25 FC (1.2 mm mist) and WR of 5 mm h^–1,and 6.6 h in the soil with 620 g kg^–1 clay, with AMC of0.5 FC (5.4 mm mist) and WR of 1 mm h^–1.

After prewetting and 15 min break for moisture redistribution,the trays were exposed to a simulated rainstorm of 80 mm ofdeionized water. When rainwater percolating through the soilwas detected at the outlet of the trays, leachate was collectedand measured at regular times during the rainstorm to determinethe IR. Likewise, the runoff from the entire rainstorm was collectedand measured. The weight of soil that was eroded from each soiltray was measured by drying the runoff samples and weighingthe dry soil. The measured soil loss could be assumed to representinterrill erosion because the trays in the rainfall simulatorwere short (0.5 m) (Meyer and Harmon, 1984).

Infiltration data obtained from the rainfall simulator wereanalyzed using Eq. [1] proposed by Morin and Benyamini (1977):

[2]
where I_t is instantaneous infiltrationrate (mm h^–1); I_i is initial infiltration rate (mm h^–1);I_f is final infiltration rate (mm h^–1); ${gamma}$ is soil coefficientrelated to surface aggregate stability (mm^–1); t is timefrom the beginning of the storm (h), and p is rain intensity(mm h^–1).

A nonlinear regression program used measured I_t, I_f, and p valuesto calculate I_i and ${gamma}$ that gave the best coefficient of determination(R² > 0.9) between paired calculated and measured I_t values.

Runoff volume (Roff) for any given depth of rain (N) from eachsingle event was calculated using Eq. [3]:

[3]
whereI_t is the calculated instantaneous infiltration rate for intervalnumber j, p is the rain intensity, and d_j is depth of rain appliedduring interval number j (d was taken as 1 mm for all intervals).For cases where (I_t)_j > p, (I_t)_j was taken as equal to p. Wepreferred to use calculated runoff values rather than measuredrunoff data because of water splash from the soil boxes, whichcould amount to 15% of the applied rain.

Statistical Analysis
All the studies were conducted in three replicates. Runoff andsoil loss data were subjected to a multifactor analysis of variance(SAS Institute, 1995). In cases where interactions were notedamong treatments, differences among runoff or soil loss of individualtreatments were determined using a single confidence intervalvalue at level P $≤$ 0.05 (SAS Institute, 1995).

RESULTS AND DISCUSSION

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

Aggregate Disintegration, Seal Formation, Infiltration Rate, and Runoff
The IRs as a function of cumulative rainfall for three soilswith two WRs and three AMCs are presented in Fig. 1 . In alltreatments and soils, the IR decreased as cumulative rainfallincreased until a final IR was reached. This decrease in IRduring rainfall resulted from an increase in water content inthe soil layer (which decreased the matric potential gradient),and the formation of a seal at the soil surface (Morin et al., 1981).The results in Fig. 1 indicated that the effects of AMCand WR treatments on IR and seal formation were different inthe three soils. Also, interactions between AMC and WR in theireffect on seal formation were observed.

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Fig. 1. Infiltration rate as a function of cumulative rainfall for the three soils (with 230, 410, and 620 g kg^–1 clay), two WR treatments (1 and 5 mm h^–1), and three antecedent moisture content (AMC) treatments (air dry, 0.25 and 0.5 field capacity). Rain intensity was 42 mm h^–1. Bars indicate standard deviation.

The final IR can be used as an index to characterize seal formationand its properties. In general, the lower the final IR, themore developed is the seal (Morin et al., 1981). The final IRof the air-dry soils (exposed to the simulated rain) and thosewith AMC of 0.5 FC and WR of 1 mm h^–1 are presented inFig. 2 . In the air-dry soil, the WR of the soil surface wasequal to the rain intensity (42 mm h^–1). The effect ofslow wetting on the final IR of the soils with 230 and 410 gkg^–1 clay was small (Fig. 2). Conversely, the final IRof the soil with 620 g kg^–1 clay was significantly higherthan the final IR of the other two soils at each of the WR treatmentsand the effect of AMC on the final IR was significant (Fig. 2).This high final IR in the soil with 620 g kg^–1 claywas due to its high aggregate stability (Shainberg et al., 2001;Mamedov et al., 2002).

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Fig. 2. Final infiltration rate of the three air-dried soils and the three soils prewetted to AMC of 0.5 FC with a WR of 1 mm h^–1. Values of a treatment in different soils followed by the same upper case letter and values of the treatments within a soil followed by the same lower case letter are not significantly different ( ${alpha}$ = 0.05).

Wetting the aggregates weakens the cementing forces betweenparticles inside the aggregate and renders the aggregates easierto break down (Ghezzehei and Or, 2000). However, subjectingair-dry soil to high intensity rain caused more aggregate breakdownand seal formation compared with soil prewetted with slow WR(Fig. 2). These results indicated that fast wetting of dry soilwith 620 g kg^–1 clay by high intensity rain (42 mm h^–1)enhanced aggregate slaking and seal formation. Conversely, inthe soils with 230 and 410 g kg^–1 clay, the effect ofWR on the final IR value was small (Fig. 2). These results indicatedthat the role of aggregate stability and slaking in seal formationin these soils were negligible.

As a result of the increase in aggregate stability with theincrease in clay content, we should expect the final IR of thesoil with 410 g kg^–1 clay to be intermediate between thesoils with 230 and 620 g kg^–1 clay. Also, the responseof the soil with 410 g kg^–1 clay to WR should be intermediatebetween the two soils. However, the results in Fig. 2 indicatethat the soil with 410 g kg^–1 clay was equally susceptibleto sealing and equally insensitive to WR as the soil with 230g kg^–1 clay. These discrepancies are explained by consideringthe effect of clay content on aggregate strength, aggregateslaking, and the response of soils to raindrop impact energy.

Aggregate stability could be affected by soil properties likeorganic matter, clay, and CaCO₃ content or exchangeable sodiumpercentage (Kay and Angers, 1999). Linear regressions betweenMWD, as determined by slow wetting of the aggregates in water,and these soil properties were used to identify their effectof these properties on aggregate stability in these soils. Theparameters of the regressions are shown in Table 2. Only therelation between MWD after slow wetting and clay content ofthe soil was found to be significant (Fig. 3A , Line a), whichindicates that in these soils, this soil property is the mainone responsible for aggregate stability. When the soil was wettedslowly, no slaking of the aggregates took place and MWD increasedlinearly with clay content (Fig. 3A, Line a), likely due tothe cementing effect of the clay within the aggregates (Kemper and Koch, 1966;Kay and Angers, 1999).

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Table 2. Parameters of the regression between mean weight diameter (MWD) values calculated from the slow wetting of the soils method and organic matter (OM), clay and CaCO₃ contents, and exchangeable sodium percentage (ESP) of the soils.

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Fig. 3. (A) Mean weight diameter (MWD) determined by fast and slow wettings as a function of clay content in the soil. Regressions are significant at P < 0.05. (B) Slaking values (difference between fast and slow MWD) as a function of the clay content in the soil. Bars indicate standard deviation.

The effect of clay content on aggregate slaking was determinedby the fast wetting method (Fig. 3A, Line b). When the dry aggregateswere exposed to fast wetting, extensive slaking took place andthere was no increase in aggregate stability with an increasein clay content (Fig. 3A, Line b). Aggregate slaking is givenby the differences between values in Lines a and b in Fig. 3Aand is presented in Fig. 3B. Aggregate slaking by fast wettingincreased linearly with an increase in clay content (Fig. 3B).With an increase in clay content, there is an increase in theslaking mechanisms (e.g., differential swelling and explosionof entrapped air) that compensate for the increase in aggregatestability.

The effect of soil properties (e.g., clay content) and soilconditions (e.g., WR and AMC) on IR and seal properties (Fig. 1and 2) can be explained by the interaction between clay content,aggregate strength and aggregate slaking, and rain impact energy.In the soils with 230 and 410 g kg^–1 clay, aggregate stabilityis relatively low and raindrop impact is enough to break downthe aggregates and to form a seal (Betzalel et al., 1995). Thus,the differences in the final IR values between the air-dry soilsexposed to 42 mm h^–1 rain and soils prewetted with WRof 1 mm h^–1 to AMC of 0.5 FC were small (Fig. 2). Conversely,in the soil with 620 g kg^–1 clay, aggregate strength washigh and aggregate breakdown by raindrop impact was not enoughto disintegrate completely the aggregates and to form a seal(Fig. 1). Thus, slaking of the aggregates by fast WR beforeraindrop impact enhanced the formation of a seal with low finalIR (Fig. 2).

The interaction between AMC (dry soil, 0.25 and 0.5 FC) andWR (1 and 5 mm h^–1) in their effect on seal formationfor the three soils with different clay contents is presentedin Fig. 4 . The effect of AMC and WR on the final IR valuesof the soils with 230 and 410 g kg^–1 clay were small andnot significant (Fig. 4). In these soils, aggregate stabilitywas so low that raindrop impact was enough to form a seal andthe final IRs of both soils were not affected by WR and AMC(Fig. 4). Conversely, in the soil with 620 g kg^–1 claya significant interaction between AMC and WR on seal formationand final IR values was observed (Fig. 4). In this soil, increasingthe WR from 1 to 5 mm h^–1 decreased the final IR valuesfor the high AMC level, and had no significant effect in thelow AMC level (Fig. 4). In the soil with 620 g kg^–1 clayand 0.5 FC AMC level, 10 mm of water were applied. This depthof water applied at WR of 5 mm h^–1 was enough to disintegratethe aggregates and the final IR was similar to that of dry soilexposed to simulated rain (Fig. 4). When the soil with 620 gkg^–1 clay was wetted to AMC level of 0.25 FC (applicationof only 5-mm water), there was not enough water to disintegratethe aggregates in either WR treatment; therefore the final IRof the clay soil was not affected by WR (Fig. 4). However, thiswetting was enough to decrease slaking by high intensity rain,causing the final IR to be significantly higher than that ofdry soil exposed to high intensity rain. Similarly, the effectof AMC depended on WR. At WR of 1 mm h^–1, increasing theAMC from 0.25 to 0.5 FC increased significantly the final IR(Fig. 4). Slowly increasing the moisture content of the soilbefore the rain prevented the aggregates from slaking by therapid wetting (42 mm h^–1) during the rainstorm. Consequently,at AMC of 0.5 FC, the soil surface became less susceptible toseal formation and IR reduction than at AMC of 0.25 FC. In contrast,for the fast WR (5 mm h^–1), increasing the AMC from 0.25to 0.5 FC decreased significantly the final IR (Fig. 4). Inthis case, probably, fast wetting (5 mm h^–1) of the soilup to 0.5 FC before the simulated rain caused more aggregateslaking than wetting up to 0.25 FC. Consequently, the totalaggregate disintegration during the prewetting and the rainstorm in the treatment of AMC of 0.5 FC and WR of 5 mm h^–1was larger than in the treatment of AMC of 0.25 FC and WR of5 mm h^–1.

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Fig. 4. Final infiltration rate of the three soils as a function of wetting rate (WR) and antecedent moisture content (AMC) treatments. Values of a treatment in different soils followed by the same upper case letter and values of the treatments within a soil followed by the same lower case letter are not significantly different ( ${alpha}$ = 0.05).

Soil Loss
Soil loss values from the three soils at three AMC and two WRlevels are presented in Fig. 5 . The effect of the wettingtreatments on soil loss during the 80 mm of simulated rain wasmore pronounced than that on runoff (Fig. 5 and Table 3). WhereasIR and runoff production depend mostly on seal formation, soilerosion is controlled by detachment of soil material from soilmass by raindrop impact and sediment transport by runoff orsplash. Soil detachment depends also on seal strength, and anincrease in seal strength causes less detachment. Thus, soilloss, being dependent on two mechanisms that are controlledby seal formation (runoff production and detachment) is moresensitive than runoff production to seal formation. These mechanismsexplain the soil losses presented in Fig. 5.

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Fig. 5. Total soil loss of the three soils obtained with three wetting rates (WR) and three antecedent moisture content (AMC) treatments. Values of a treatment in different soils followed by the same upper case letter and values of the treatments within a soil followed by the same lower case letter are not significantly different ( ${alpha}$ = 0.05).

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Table 3. Total runoff from three soils and different treatments of three antecedent moisture content and prewetting rate treatments.

In general, for each wetting treatment, soil loss from the soilwith 620 g kg^–1 clay was the smallest and soil loss fromthe soil with 410 g kg^–1 clay was the highest, among thethree soils (Fig. 5). Similar findings were reported by otherauthors (e.g., Ben-Hur et al., 1985; Mamedov et al., 2002; Meyer and Harmon, 1984).The soil with the highest clay content (620g kg^–1) produced low runoff (Table 3) and low sedimentconcentration in the runoff due to the big size of the entrainedparticles (Mamedov et al., 2002). Combination of low runoffand low sediment concentration in runoff resulted in low soilloss. Soil loss from the soil with 410 g kg^–1 was higherthan that from the one with 230 g kg^–1 clay and 360 gkg^–1 silt, in spite of the similar values of runoff inthese two soils (Table 3). Interrill erosion is also affectedby crust strength and soils with 200 g kg^–1 clay and 300g kg^–1 silt develop crust with the highest strength andlow detachment rate (Bradford et al., 1987). Thus, the claysoil with 410 g kg^–1 clay was more erodible than the loamwith 230 g kg^–1 clay in spite of the similar runoff values.

For each soil, soil loss was the highest in the air-dry treatmentand decreased on prewetting before the simulated rainfall (Fig. 5).This decrease was more pronounced as the WR was slower,in spite of the fact that runoff in the soils with 230 and 410g kg^–1 clay was not affected significantly by WR (Table 3).The notable effect of WR on soil loss and the smaller effectof WR on runoff in these soils suggest that WR had no significanteffect on the hydraulic properties of the seal in them, buthad a significant effect on the detachment rate and entrainmentof soil particles in runoff. In soils with low to moderate aggregatestability, the high impact energy of raindrops was enough todisintegrate the aggregates and to form a seal whose hydraulicproperties were unaffected by WR and AMC. However, during theslow WR and high AMC, increase in cohesion between soil particlestook place (Sirjacobs et al., 2001) resulting in higher shearstrength of surface seal and bigger detached particles so thatsediment entrainment and soil loss decreased. Mamedov et al. (2002)also reported that a decrease in WR decreased the amountof soil loss, and this effect was more evident as clay contentin the soil increased.

The response of soil loss to AMC depended on clay content andWR (Fig. 5). In the soil with 230 g kg^–1 clay, a trend(not significant) in soil loss was found between the 0.25 and0.5 FC treatments in both WR levels (Fig. 5). In this soil,the seal strength controlled soil detachment, and seal strengthwas slightly affected by AMC (Sirjacobs et al., 2001). Withincrease in AMC, seal strength increased and soil loss decreased.In the soil with 410 g kg^–1 clay, the role of seal strengthand soil detachment in sediment delivery was small and no effectof AMC, on both runoff and soil loss was observed. In the soilwith 620 g kg^–1 clay, AMC had an effect on both, soilloss and runoff and this effect was explained above. Prewettingthe clay soil with 5 mm h^–1 resulted in some aggregateslaking and a slight increase in both, runoff and erosion (Table 2and Fig. 5). When this soil was prewetted with 1 mm h^–1mist, a decrease of soil loss and runoff with increasing AMCwas observed. This phenomenon was explained by assuming thatWR of 5 mm h^–1 was fast enough to produce some slakingof the aggregates and increasing AMC increased the amount ofslaked aggregates and detached clay particles, which contributeto seal development.

CONCLUSIONS

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

In this study, the effects of clay content, WR, and AMC on sealformation and interrill erosion and their relation to aggregateslaking were studied. Aggregate stability increased with anincrease in clay content in the range between 80 and 630 g kg^–1clay. This increase in aggregate stability was due to the cementingeffect of the clay. However, at the same time, slaking by fastwetting also increased with an increase in clay content. Whereasin the soils with 230 and 410 g kg^–1 clay aggregate stabilitywas relatively low and the impact of rain drops was enough todisintegrate the aggregates and to form a seal, in the soilwith 620 g kg^–1 aggregate stability was high and whenslaking was reduced by low WR, the impact of rain drops wasnot enough to disintegrate completely the aggregates and sealformation was also reduced. In this soil, slaking of the aggregatesby fast WR before the impact of raindrops enhanced the formationof a seal with low final IR. Thus, a significant interactionbetween AMC and WR in seal formation was found in the soil with620 g kg^–1 clay, while no interaction was found in thesoils with 230 and 410 g kg^–1 clay.

The effect of the wetting treatments on soil loss during the80 mm of simulated rain was more pronounced than the effectof these treatments on runoff. Whereas the IR and runoff productiondepended mostly on seal formation, soil erosion is controlledby detachment of soil material from soil mass by raindrop impactand the transport of the resulting sediments by runoff or splash.Detachment of sediments from the soil surface depends also onseal strength, and with an increase in seal strength there isless detachment. Thus, soil loss, being dependent on two mechanismsthat are controlled by seal formation (runoff production anddetachment) was more sensitive than runoff production to differencesin WR and AMC.

Most of the studies conducted on seal formation, IR, and interrillerosion were based on results obtained in air-dry soils thatwere exposed to fast WRs. However, in field conditions the soilscan be wetted at different rates, according to the differentrain intensities in different seasons, to different antecedentmoisture content before they are exposed to high intensity rainstorms.These different wetting conditions can change the response ofthe soil to seal formation after tillage. For example, in Mediterraneanclimate, it can be expected that soil erosion will be higherin fall, when events of heavy rain fall on dry soil, than inspring, when events of rain start with low intensity, wettingthe soil before the high intensity rain.

The implications of this study are quite relevant for soil erosionmodeling. Most of the existing models have developed experimentalregressions, which consider a constant detachability and declineof IR of the soil, related to intrinsic properties like sandor clay content. However, as indicated in this study, soil detachability,final infiltration of the seal and soil erodibility are dependentnot only on these intrinsic properties, but also on soil conditionsbefore rainfall, like WR and AMC. Therefore, to improve theaccuracy of the erosion models, it is suggested that these parametersshould be taken into account.

ACKNOWLEDGMENTS

This work was partly funded by the EU Marie Curie fellowshipunder the contract no. EVK1-CT-202-50020, and by the Ministryof Science, Culture and Sport (Israel) and the Bundesministeriumfuer Bildung and Forscung (Germany) under GLOWA JR project.

NOTES

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

Contribution from the Agricultural Research Organization, theVolcani Center, no. 607, 2004 series.

Received for publication January 15, 2004.

REFERENCES

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

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