Organic Matter and Aggregate Size Interactions in Infiltration, Seal Formation, and Soil Loss

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DIVISION S-6—SOIL & WATER MANAGEMENT & CONSERVATION

Organic Matter and Aggregate Size Interactions in Infiltration, Seal Formation, and Soil Loss

M. Lado^a, A. Paz^b and M. Ben-Hur^*^,a

^a Inst. of Soil, Water, and Environmental Sci., The Volcani Center, Agricultural Research Organization, P.O. Box 6, Bet Dagan, 50250, Israel
^b Faculty of Sci., Univ. of La Coruna, A Zapateira s/n, 15071 La Coruna, Spain

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

ABSTRACT

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

The objectives of this study were to investigate (i) the effectof soil organic matter (OM) content on the mechanisms that forma seal, and (ii) the OM content and aggregate size interactionsin seal properties, infiltration rate (IR), and soil loss. Twosamples of sandy loam (Humic Dystrudept) designated low-OM soil(2.3% by weight OM) and high-OM soil (3.5% OM) were studied.Aggregate sizes <2, 2 to 4, and 4 to 6 mm of each soil wereexposed to 80 mm of simulated rainfall with an intensity of42 mm h^–1. The final IR increased with increasing aggregatesize from 4.2 to 5.2 mm h^–1 in the low-OM soil, and from5.8 to 10.8 mm h^–1 in the high-OM soil. There was a significantinteraction between OM content and aggregate size in seal formationand final IR. The low aggregate stability and the high dispersivityof the low-OM soil allowed the development of a dense and thickcrust for all the aggregate sizes. Conversely, the high aggregatestability and the low dispersivity of the high-OM soil limitedthe seal formation. Consequently, the IR values were high anddifferences in IR among the three aggregate sizes in this soilwere relatively high. The soil losses increased with increasingaggregate size, ranging from 4.5 x 10^–3 to 6.6 x 10^–3kg m^–2 mm^–1 in the low-OM soil, and from 1.2 to3.8 x 10^–3 kg m^–2 mm^–1 in the high-OM soil.In this case, no significant interaction was found between soilOM content and aggregate size.

Abbreviations: CEC, cation exchange capacity • DI, dispersion index • EC, electrical conductivity • IR, infiltration rate • MWD, mean weight diameter • OM, organic matter • SAR, sodium adsorption ratio • SEM, scanning electron microscope

INTRODUCTION

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

THE SOIL STRUCTURE after tillage tends to collapse during irrigationor rainfall, and this structural dynamic considerably altersthe soil hydraulic properties (Hillel, 1980; Ben-Hur et al., 1989;Or and Ghezzehei, 2002). Therefore, it is important togain an insight into the processes and mechanisms that causethese structural changes. The OM content in soil was found tobe one of the main factors controlling the aggregate stabilityof soils with low exchangeable sodium percentage (Chaney and Swift, 1984;Elliot, 1986; Benito and Diaz-Fierros, 1992; Golchin et al., 1995).Soil OM compounds bind the primary particlesin the aggregate, physically and chemically, and this, in turn,increases the stability of the aggregates and limits their breakdownduring the wetting process (Emerson, 1977). Tisdall and Oades (1982)classified these organic binding agents into (i) transient:mainly polysaccharides; (ii) temporary: roots and fungal hyphae;and (iii) persistent: resistant aromatic components associatedwith polyvalent metal cations, and strongly sorbed polymers.Tisdall and Oades (1982) concluded that macroaggregates (>0.25mm in diameter) are weaker than microaggregates (<0.25 mmin diameter) because the former are stabilized by transientbinding, such as roots, hyphae, and polysaccharides, whereasthe latter are bound by persistent aromatic humic material associatedwith amorphous iron and aluminum compounds.

Lado et al. (2004) found that for aggregate sizes of <2 and2 to 4 mm under absence of raindrop impact, the saturated hydraulicconductivity of the soil with high OM content (3.5%) was higherthan that of the low-OM (2.3%) soil. These differences in thehydraulic conductivity between the two soils resulted from structuraldegradation that occurred to a greater extent in the low-OMsoil than in the high-OM one. During the leaching of the soilswith tap water [electrical conductivity (EC) = 0.9 dS m^–1and sodium adsorption ratio (SAR) = 2.5 (mmol L^–1)^0.5],aggregate slaking was the main mechanism that degraded the soilstructure. Leaching the soils with deionized water led to furtherreductions of the saturated hydraulic conductivities of thelow-OM soil with aggregate sizes of <2 and 2 to 4 mm, andof the high-OM soil with <2-mm aggregates. These decreasesresulted from clay dispersion that was larger in the low- thanin the high-OM soil.

When the soil surface is exposed to raindrop impact, the permeabilityof the soil is affected by seal formation (Morin et al., 1981;Ben-Hur and Letey, 1989). The seal formation reduces the infiltrationrate (IR), thus increasing runoff (Morin et al., 1981) and mayincrease the soil loss (Ben-Hur et al., 1992). In general, thelower the aggregate stability at the soil surface, the higherthe susceptibility of the soil to seal formation (Le Bissonnais, 1996)and to soil loss (Singer et al., 1982). Thus, under raindropimpact, the mechanisms that affect the soil hydraulic propertiescould be different from those in the absence of raindrop impact.

McIntyre (1958) found that a seal consists of two distinct parts:an upper skin seal attributed to compaction by raindrop impact,and a washed-in zone of decreased porosity, attributed to theaccumulation of small particles. Agassi et al. (1981) suggestedthat the seal formation is a result of two complementary mechanisms:(i) a physical disintegration of surface soil aggregates causedmainly by the impact energy of the raindrops that leads to theformation of the upper skin layer; and (ii) the physicochemicaldispersion of soil clays, which migrate into the soil with theinfiltrating water and clog immediately beneath the surfaceto form the washed-in zone.

Organic matter content could decrease the susceptibility ofthe soil to seal formation. Le Bissonnais and Arrouays (1997)found that reduction of the organic carbon content of a loamysoil below 1.5 to 2.0% decreased the aggregate stability andthe soil IR under rainfall simulator conditions. Ekwe (1991)used a rainfall simulator to measure the soil detachment fromfive different soils with OM contents ranging from 1.2 to 5.6%,and found that the soil detachment decreased significantly asthe OM content increased. Likewise, Fullen (1991) indicatedthat loamy sand with OM contents <2% were very prone to erosion.Guerra (1994) used a rainfall simulator to measure IR, runoff,and soil loss in sandy loam soils with various OM contents,and found that the soil OM content played an important rolein aggregate stability and soil erodibility. Guerra (1994) foundthat an OM content of 3% was a threshold value, below whichthe aggregates were unstable and the soil erodibility was high.However, in spite of the dominant effect of the OM content onseal formation, there is little information on the effects ofthe OM on the two mechanisms, the physical disintegration ofsurface soil aggregates and the physicochemical dispersion ofsoil clays (Agassi et al., 1981), that form the seal.

The initial size of aggregates in the soil is also an importantfactor in seal formation, IR, runoff, and soil loss (e.g., Moldenhauer and Kemper, 1969;Ekwe, 1991; Freebairn et al., 1991; Shainberg et al., 1997).Moldenhauer and Kemper (1969) and Freebairn et al. (1991)indicated that as the initial aggregate size of thesoil increased, the IR during a rainstorm dropped more graduallybecause of a delay in seal formation. However, the final IRof the studied soils was independent of the initial aggregatesize. Shainberg et al. (1997) studied the effects of aggregatesize of two soils containing 465 and 190 g kg^–1 clay and2.07 and 1.49% OM, respectively. In both soils, the aggregatestability increased and the seal formation rate decreased whenthe initial aggregate size increased from <4 to between 9.5and 12 mm.

Many studies have been focused on the effects of OM contentand aggregate size on seal formation and soil loss. We hypothesizedthat there are interactions between aggregate size, OM content,and aggregate stability, and that these interactions affectseal formation, IR, and soil loss. However, little is knownabout these interactions and their effects on the above parameters.Thus, the objectives of the present study were (i) to investigatethe effect of soil OM content and aggregate size on the mechanismsthat form the seal; and (ii) to study the OM content and aggregatesize interactions in seal formation and morphology, IR, andsoil loss under raindrop impact conditions.

MATERIALS AND METHODS

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NOTES
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Soil Samples
Two soil samples with differing OM contents were collected fromthe 0.05- to 0.15-m layer in two adjacent fields: a cultivatedcornfield and grassland with minimum tillage, in La Coruna,northwestern Spain. This region is characterized by a temperatehumid climate, with average annual rainfall of 1171 mm, mainlyfrom October to April. Some physical and chemical propertiesof the soils are presented in Table 1. The mechanical compositionwas determined by means of a hydrometer (Day, 1956), the OMcontent by the Walkley-Black method (Allison, 1965), the CaCO₃content by a volumetric method (Allison and Moodie, 1965), andthe cation exchange capacity (CEC) by extraction with ammoniumacetate at pH 7 (Chapman, 1965). The soil samples from bothfields were sandy loam, Humic Dystrudept (Soil Survey Staff, 1999),and had similar properties except for the OM contentsand the CECs (Table 1). It should be noted, however, that thedifference in the CEC values was most likely a result of thedifferences in the OM contents in these two soil samples. Thesoil with 2.3% OM was referred to as the low-OM soil and thatwith 3.5% as the high-OM soil.

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Table 1. Mechanical composition, CaCO₃ content, cation exchangeable capacity (CEC), exchangeable sodium percentage (ESP), organic matter (OM) content, pH, electrical conductivity (EC), sodium adsorption ratio (SAR), and mineralogy for the two studied soils and various aggregate sizes (AS).

The soil samples were air dried, visible roots and organic residueswere removed, and the dry samples were sieved to obtain variousgroups of aggregates with size ranges of <2, 2 to 4, and4 to 6 mm. The mechanical composition and OM and CaCO₃ contentsin the two soil samples were also determined for each aggregatesize. The soil properties of the various aggregate sizes ineither soil were not significantly different, except the OMcontent in the 4- to 6-mm aggregate size of the low-OM soilwhich was significantly higher than those in the other aggregatesizes (Table 1). The two soils were subjected to the followingstudies.

Fast-Wetting Aggregate Stability Test
The soil aggregate stability was determined by the fast-wettingmethod proposed by Le Bissonnais (1996). This method was chosenbecause in the rainfall simulator study, which is describedbelow, the soils were under fast-wetting conditions (Levy et al., 1997).For each soil, aggregates of <2 or 2 to 4 or4 to 6 mm were put in the oven at 40°C for 24 h, and 5 gof the oven-dry aggregates were gently immersed in a beakercontaining 50 cm³ of deionized water for 10 min. The water wasthen sucked off with a pipette. The soil material was transferredto a 50-µm sieve that had previously been immersed inethanol and gently moved up and down in ethanol five times toseparate the <50-µm fragments from the >50-µmones. The >50-µm fraction was oven dried and then gentlydry sieved by hand on a column of sieves of mesh sizes 4.00,2.00, 1.00, 0.50, 0.25, 0.10, and 0.05 mm. The weight of eachfraction was then calculated; that of the <50-µm fractionwas the difference between the initial weight and the sum ofthe weights of the other seven fractions. The aggregate stabilityfor each soil sample was expressed by calculating the mean weightdiameter (MWD) of the eight classes:

[1]
wherew_i is the weight fraction of aggregates in the size class iwith a diameter _i.

Rainfall Simulator Study
The IR and the soil loss were determined by means of a laboratoryrainfall simulator (Morin et al., 1967). The typical mechanicalparameters of the simulated rainfall were: rainfall intensity,42 mm h^–1; raindrop mean diameter, 1.9 mm; median dropvelocity, 6.2 m s^–1; and kinetic energy, 18.1 J m^–2.

The soil samples were placed in perforated trays measuring 0.30by 0.50 m and 0.02 m deep. For all the aggregate sizes tested,a 1-cm-thick layer of soil with aggregate size of <2 mm waspacked on the bottom of the tray. Above this layer was packeda 1-cm-thick layer of soil with the tested aggregate size. Thebulk densities of the upper layer for the <2-, 2- to 4-,and 4- to 6-mm aggregate sizes were 1.32, 1.06, and 0.98 Mgm^–3, respectively. The packed soil tray was placed onan 8-cm-thick layer of coarse sand, in a box positioned underthe rainfall simulator at a slope of 9%. The experimental treatmentscomprised the various initial aggregate sizes and the soil OMcontents.

The soils in the rainfall simulator were wetted almost to saturationwith tap water [EC = 0.9 dS m^–1 and SAR = 2.5 (mmol L^–1)^0.5]introduced from below, and were then exposed to a simulatedrainstorm of 80 mm of deionized water. Water percolating throughthe soil was collected and measured at various times duringthe rainstorm, to determine the IR. Likewise, the runoff fromthe entire rainstorm was collected and measured. The soil thatwas eroded from each soil tray was measured by drying the runoffsamples and weighing the dry material. Because the length ofthe tray in the rainfall simulator was short (0.5 m), the measuredsoil loss could be considered because of interrill erosion (Meyer and Harmon, 1984).Nine grams of the eroded material from eachsoil tray were analyzed by the hydrometer method (Day, 1956)to determine the clay content in the sediment.

Scanning Electron Microscope Observations
After the rainstorms, the trays with the sealed soils were air-driedfor a week. A piece of crust from the <2 and 4- to 6-mm aggregatesize samples of each soil was carefully broken, along its naturalplanes of weakness, into representative fragments from the 0-to 15-mm increment. The top of the crust was mechanically stabilizedby coating it with a gold layer. The crust sample was attachedto the scanning electron microscope (SEM) stub with conductivecarbon glue, and the fracture was covered by sputtering witha thin layer of gold, approximately 40 nm in thickness. Thesamples were then placed in the SEM and micrographs were taken.

Statistical Analysis
All the studies were conducted in three replicates, and thedifferences of the means and the interaction between studiedparameters were tested with ANOVA as a complete randomized design.Separation of means was subjected to Tukey's honestly significantdifference test (Steel and Torrie, 1960). All tests were performedat the 0.05 significance level.

RESULTS AND DISCUSSION

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

The MWD values for each aggregate size for both the low- andhigh-OM soils determined by the fast-wetting method are presentedin Table 2. A higher MWD value indicates a higher aggregatestability of the tested soil (Le Bissonnais, 1996). Hence, theresults in Table 2 show that for each aggregate size, the aggregatestability of the high-OM soil was significantly higher thanthat of the low-OM soil. The high OM content in the former soilacted as a cement, holding the particles in the aggregate togetheragainst the disruption forces during the wetting process, whereasin the low-OM soil the OM content was too low to prevent theaggregate breakdown. Because of the different initial sizesof the tested aggregates, comparison of MWD values between theaggregate sizes in each soil is not possible. However, the ratiobetween the MWD values of the high-OM soil and the low-OM soil(Table 2) indicated that the increase of OM had a more pronouncedeffect in aggregate stability as aggregate size was bigger.This issue is discussed below.

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Table 2. Mean weight diameter (MWD) for each aggregate size for both the low- and high-OM soils, and ratio between MWD of the high- and of the low-OM soil for each aggregate size.

The IRs for each aggregate size for both the low- and high-OMsoils are presented in Fig. 1 as functions of the cumulativerainfall. For all the treatments (various aggregate sizes andOM contents), the IR decreased as the cumulative rainfall increased,until a final IR was reached. These final IR values of the twosoils and the various aggregate sizes and the cumulative infiltrationuntil the final IR was attained are presented in Table 3. Becausethe IR measurements were conducted mainly under saturation conditions,the decrease of the IR during the rainstorm could be a resultof two main mechanisms (Hillel, 1980): (i) a decrease of thehydraulic conductivity of the soil layer; or (ii) formationof a seal at the soil surface. Lado et al. (2004) found thatwetting and leaching of the same soils in the absence of raindropimpact led to soil structure degradation, which in turn decreasedthe saturated hydraulic conductivity. This structural degradationwas caused by aggregate slaking, and clay swelling and dispersion.Under these conditions, the saturated hydraulic conductivitiesof the low- and high-OM soils with <2-mm aggregates, afterleaching with >9 pore volumes of deionized water, were 7.0 and14.4 mm h^–1, respectively (Lado et al., 2004). However,the final IRs of the low- and high-OM soils with the variousaggregate sizes, under raindrop impact, were <5.4 and <10.8mm h^–1, respectively (Table 3). These results indicatethat the decrease of the IR with accumulating rainfall (Fig. 1)was mainly a result of increasing destruction of the soilsurface structure by the impact of the raindrops. This destruction,in turn, led to the formation of a seal at the soil surface.The photographs of the soil surface before and after the rainstormsin the various treatments (Fig. 2) support this interpretation.Likewise, Morin et al. (1981) and Ben-Hur and Letey (1989) reacheda similar conclusion, that the decrease of IR under raindropimpact was caused mainly by seal formation.

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Fig. 1. Infiltration rate as a function of cumulative rainfall for the two soils characterized by different organic matter (OM) content and the three different aggregate sizes. Bars indicate standard deviation.

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Table 3. Final infiltration rate (IR) and cumulative infiltration until attainment of final IR in two soil samples having differing organic matter (OM) contents and various aggregate sizes.

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Fig. 2. Photographs of the surface before and after a rainstorm of 80 mm for the two soils with different organic matter (OM) content and different aggregate sizes.

The rate of seal formation during the rainstorm can be consideredto be inversely related to the cumulative amount of water infiltrateduntil attainment of the final IR: less accumulation of infiltratedwater indicates quicker seal formation (fast seal formationrate). For each aggregate size, the final IR was significantlyhigher and the seal formation rate was significantly lower forthe high-OM soil than for the low-OM soil (Table 3). These differencesin the final IR values and seal formation rates of the two soilsmost likely resulted from the effect of the OM on the structureof these two soils and consequently on seal formation.

The seal formation process comprises two main stages (Mcintyre, 1958;Agassi et al., 1981; Morin et al., 1981): (i) breakdownof the aggregates and dispersion of clay at the soil surface;and (ii) rearrangement of these detached particles into a seallayer. The small, detached particles at the impacted soil surfacecan form a compacted sealing skin with low hydraulic conductivity,whereas the dispersed clay can move from the soil surface withthe infiltrating water to form the washed-in zone (Mcintyre, 1958;Gal et al., 1984; Wakindiki and Ben-Hur, 2002). Ben-Hur and Letey (1989)found that clay dispersion at the soil surfacesignificantly controls the final IR and the rate of seal formation.Clay dispersion at the soil surface can occur when rainwater(distilled water) reduces the electrolyte concentration at thesoil surface below the flocculation value (Agassi et al., 1981).

Soil dispersibility under rainfall conditions was expressedas a dispersion index (DI), which was calculated by dividingthe percentage of clay in the runoff sediments by that in theoriginal soil (Stern et al., 1991). A DI value of 1 indicatesthat no clay dispersion occurred at the soil surface duringthe rainstorm. In contrast, when the clay fraction at the soilsurface is dispersed, the clay percentage in the sediments shouldbe higher than that in the original soil because the clay particlesare more easily transported by the overland flow than the biggersilt and sand particles. In this case, the DI > 1: the higherthe DI, the more dispersive the soil.

Dispersion indices for the various aggregate sizes of the twosoils are presented in Fig. 3 . The DI values of the high-OMsoil for all three aggregate sizes were ${approx}$ 1, which indicates thatin this soil, clay dispersion at the surface during the rainstormwas insignificant; it is likely that the cementing effect ofthe 3.5% OM in this soil limited the clay dispersion at thesoil surface. In contrast, the DI values of the low-OM soilfor all three aggregate sizes were >2.1, significantly higherthan that of the high-OM soil (Fig. 3), indicating that highclay dispersion had occurred at the low-OM soil surface duringseal formation.

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Fig. 3. Dispersion index (DI) of the two soil samples with differing organic matter (OM) contents and three different aggregate sizes. Bars indicate standard deviation, and different letters above the columns indicate significant differences ( ${alpha}$ = 0.05) among the treatments.

The effects of the OM content on the mechanisms that form theseal can be determined by the crust micromorphology. Scanningelectron micrographs of the soils with the <2 and 4- to 6-mmaggregates are shown in Fig. 4 and 5 , respectively. Forboth soils and all aggregate sizes, the micromorphology of thesoil layer at depths >2 mm (Fig. 4 and 5) is that of the bulksoil, which was not affected by the raindrop impact. These SEMobservations reveal that the crust thickness of the low-OM soilwith <2-mm aggregates was ${approx}$ 1.1 mm, and that this crust wascomprised of three parts (Fig. 4): (i) the uppermost layer,from the 0- to 0.1-mm depth, containing particles ${approx}$ 0.05 mm insize with no fine materials between them; (ii) a transitionlayer, from the 0.1- to 0.45-mm depth, containing a mixtureof ${approx}$ 0.05-mm particles and fine materials; and (iii) the innermostlayer of the crust, from 0.45 to 1.1 mm, which was visuallyvery dense, probably because of the accumulation of dispersedclay that was washed in from the upper layers. This last layeris the washed-in zone. In the high-OM soil with <2-mm aggregates(Fig. 4), the thickness of the crust was ${approx}$ 0.8 mm, and it comprisedsome relatively large particles, ${approx}$ 0.1 mm in size, mixed withfine materials. In this crust, no distinct washed-in zone wasobserved.

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Fig. 4. Scanning electron micrographs of the crust and the soil beneath it, for the soils with two organic matter (OM) content and <2-mm aggregates.

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Fig. 5. Scanning electron micrographs of the crust and the soil beneath it, for the soils with two organic matter (OM) content and 4- to 6-mm aggregates.

The crusts on the two soils with 4- to 6-mm aggregates (Fig. 5)were less dense than those on the same soils with <2-mmaggregates (Fig. 4). The crust on the low-OM soil with 4- to6-mm aggregates was 1.2 mm in thickness and it was comprisedof relatively large particles, 0.05 to 0.10 mm in size, withfine materials between them. In contrast, the thickness of thecrust on the corresponding high-OM soil was ${approx}$ 0.7 mm, and it wasmainly comprised of large particles, 0.05 to 0.20 mm in size,with some fine materials but less than in the crust on the low-OMsoil. No distinct washed-in zone was observed in these two crusts.

Observations of the soil surfaces before and after the rainstorm(Fig. 2) indicated that the rainstorm caused more extensiveaggregate breakdown in the low- than in the high-OM soil forboth aggregate sizes. In the low-OM soil with both the <2-mmand 4- to 6-mm aggregates, and in the high-OM soil with the<2-mm aggregates, most of the aggregates at the soil surfacewere broken and a smooth crust was developed. However, moreunbroken aggregates were observed at the surfaces of the low-OMsoil with 4- to 6-mm aggregates and of the high-OM soil with<2-mm aggregates than at the surface of the low-OM soil with<2-mm aggregates. In contrast, in the high-OM soil with 4-to 6-mm aggregates, many fewer aggregates were broken down,and a less continuous crust was developed than on the othersoils.

The increase in the OM content in the soil increased the aggregatestability (Table 2) and decreased the soil dispersivity (Fig. 3).Therefore, it can be suggested from the photographs of thesoil surface after the rainstorm (Fig. 2) and the micromorphologiesof the crusts (Fig. 4 and 5) that the final IR values were lowerin the low- than in the high-OM soil because (i) there was moreextensive breakdown and dispersion of the aggregates at thesurface of the low-OM soil than at that of the high-OM soil,so that a more continuous crust was formed on the former soil;(ii) the rearrangements of the detached and dispersed particlesin the crust differed between the two soils, so that a thicker,higher-density crust (in some cases, with washed-in zone) formedon the low- than on the high-OM soil.

The final IRs and the rates of seal formation in the two soilswere also affected by the initial aggregate sizes (Fig. 1 andTable 3). In general, the larger the aggregate size, the greaterthe final IR and the lower the rate of the seal formation. Theeffect of the initial aggregate size on the seal formation ratewas more pronounced than its effect on the final IR. The resultspresented in Table 3 also indicate that there was a significantinteraction between soil OM content and aggregate size, in theireffects on the final IR and seal formation rate. The effectsof the aggregate size on the seal characteristics (seal formationrate and final IR) were more pronounced in the high- than inthe low-OM soil (Fig. 1 and Table 3).

This interaction between soil OM content and aggregate sizecould be explained as follows. Because of the low aggregatestability (Table 2) and the high dispersivity (Fig. 3) of thelow-OM soil, the breakdown and dispersion of the aggregatesat the surface of this soil, under raindrop impact, were extensiveeven for the large aggregate size (4–6 mm). Consequently,a well-developed seal was formed on the low-OM soil for allaggregate sizes (Fig. 2, 4, and 5), and the effect of the initialaggregate size on the IR was negligible (Fig. 1). In contrast,the higher aggregate stability (Table 2) and the lower dispersivity(Fig. 3) of the high-OM soil limited the breakdown and dispersionof the aggregates at its surface. Therefore, the differencein IR caused by the presence of large (4- to 6-mm) or small(<2-mm) aggregates under raindrop impact was relatively great(Fig. 1).

Freebairn et al. (1991) and Shainberg et al. (1997) found thatfor various smectitic soils with <3.1% OM content, initialaggregate size had significant effects on the rate of seal formation,but not on the final IR values. These results are differentfrom the results obtained in the present study (Fig. 1 and Table 3),particularly, for the high-OM soil. This was probably becausethe differences in the mineralogy of these soils. The dominantclays in the soils of the present study were vermiculite andkaolinite, but in the soils of Freebairn et al. (1991) and Shainberg et al. (1997),smectite was dominant. This smectite probablydecreased the aggregate stability (Stern et al., 1991; Wakindiki and Ben-Hur, 2002)of the soils of Freebairn et al. (1991) andShainberg et al. (1997) and, therefore, the aggregate breakdownby the raindrop impact in these soils was more extensive evenfor the soils with high OM content, and a well-developed sealwith low final IR was formed on all the soils with all aggregatesizes.

The interrill soil losses of the two soils, with the variousaggregate sizes, are presented in Fig. 6 . For each aggregatesize, the soil loss was significantly larger in the low- thanin the high-OM soil (Fig. 6). The soil losses ranged from 4.5x 10^–3 to 6.6 x 10^–3 kg m^–2 mm^–1 forthe low-OM soil and from 1.2 x 10^–3 to 3.8 x 10^–3kg m^–2 mm^–1 for the high-OM soil. In both soils,the soil loss was significantly greater for the <2-mm aggregatesthan for the other two aggregate sizes, but the soil lossesfor the two larger sizes did not differ significantly from oneanother. Unlike the final IR, no significant interaction wasfound between soil OM content and aggregate size in their effectson soil loss.

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Fig. 6. Interrill soil loss for the two soils characterized by different organic matter (OM) content and the above the columns indicate significant differences ( ${alpha}$ = 0.05) among the treatments.

Interrill erosion involves two main processes (Lane et al., 1987):(i) detachment of material from the soil surface by raindropimpact, and (ii) transport of the resulting sediment by raindropsplash and overland flow. Since splash was not determined inthe present study, the transport of the sediment was affectedonly by the runoff flow. Therefore, it can be concluded thatthe soil loss from the low-OM soil was greater than that fromthe high-OM soil (Fig. 6) because of (i) the lower aggregatestability (Table 2) and the higher dispersivity (Fig. 3), andconsequently greater soil detachment of the former; and (ii)the lower IR and, consequently, greater runoff rate and sedimenttransport in the low-OM soil.

CONCLUSIONS

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

In the studied soils, an increase of OM content from 2.3 to3.5% limited the aggregate breakdown, soil dispersivity, andthe seal formation at the soil surface under raindrop impactconditions. It was suggested that the final IR values were lowerin the low- than in the high-OM soil because (i) there was moreextensive breakdown and dispersion of the aggregates at thesurface of the low-OM soil than at that of the high-OM soil,so that a more continuous crust was formed on the former soil;(ii) the rearrangement of the detached and dispersed particlesin the crust differed between the two soils, so that a thicker,higher-density crust (in some cases, with washed-in zone) wasformed on the low- than on the high-OM soil.

There was an interaction between OM content and aggregate sizein seal formation and IR. Because of the low aggregate stabilityand the high dispersivity of the low-OM soil, the breakdownand dispersion of the aggregates at the surface of this soil,under raindrop impact, were extensive even for the large aggregatesize. Consequently, a well-developed seal was formed on thelow-OM soil for all aggregate sizes, and the effect of the initialaggregate size on the IR was negligible. In contrast, the higheraggregate stability and the lower dispersivity of the high-OMsoil limited the breakdown and dispersion of the aggregatesat its surface. Therefore, the differences in IR under raindropimpact caused by the presence of large or small initial aggregateswere relatively great in the high-OM soil.

There is a practical aspect of this interaction between OM contentand aggregate size. Cultivation of soil with high OM will beeffective because in this soil, the large aggregates will remainstable during the rainy season and will maintain relativelyhigh IR. In contrast, in soil with low OM, the cultivation willhave only a short-lived effect because in this soil most ofthe large aggregates will be broken down and dispersed at thebeginning of the rainy season.

ACKNOWLEDGMENTS

This work was partly funded by Xunta de Galicia, Spain; andby the EU Marie Curie fellowship under the contract no. EVK1-CT-202-50020.

NOTES

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

Contribution from the Agricultural Research Organization, TheVolcani Center, no. 623/02, 2002 series.

Received for publication July 17, 2003.

REFERENCES

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

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