Tillage and Crop Influences on Physical Properties for an Epiaqualf

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DIVISION S-6—SOIL & WATER MANAGEMENT & CONSERVATION

Tillage and Crop Influences on Physical Properties for an Epiaqualf

Humberto Blanco-Canqui^*^,a, C. J. Gantzer^a, S. H. Anderson^a and E. E. Alberts^b

^a Dep. of Soil and Atmospheric Sciences, Univ. of Missouri–Columbia, 302 Anheuser-Busch Natural Resources Building, Columbia, MO 65211
^b USDA-ARS, 246 Agricultural Engineering Building, Columbia, MO 65211

^* Corresponding author (hb91d{at}mizzou.edu).

ABSTRACT

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

Tillage impacts on soil properties differ among soils. Thisstudy investigated tillage, cropping, and wheel traffic (WT)effects of 13-yr of no-tillage (NT), chisel plow (CP), and moldboardplow (MP) under continuous corn (Zea mays L.) and soybean (Glycinemax L.) including a check treatment of continuous cultivatedfallow (CCF) on bulk density ( ${rho}$ _b), organic matter (OM), soil–waterretention, and saturated hydraulic conductivity (K_sat) on aMexico silt loam (fine, smectitic, mesic, Aeric Vertic Epiaqualf).Possible relationships between runoff and effective K_sat (K_eff)were also studied. Soil properties were determined on intactcores of 76-mm diam. collected from trafficked and nontraffickedpositions for the 0- to 100-mm and 100- to 200-mm depths fromthe Midwest Research Claypan Farm erosion plots near KingdomCity, MO. Results show that the CCF had lower ${rho}$ _b, OM, K_sat, andhigher surface runoff than other treatments (P < 0.01). Tillageeffects on soil properties among NT, CP, and MP were small andcrop dependent. Corn had lower K_sat (7.3 mm h^–1) thansoybean (11.7 mm h^–1; P < 0.01). Conversely, corn hadslightly higher ${rho}$ _b (1.53 Mg m^–3) than soybean (1.48 Mgm^–3; P < 0.01). The ${rho}$ _b increased from 1.47 to 1.52 Mgm^–3 and OM decreased from 15.5 to 14.0 g kg^–1 withdepth (P < 0.01). Wheel traffic reduced K_sat by three timesand increased ${rho}$ _b by 6% (P < 0.01). Bulk density was a significantpredictor of log K_sat (P < 0.01) but not for soils underCCF management. The K_eff was not related to runoff with theexception of the CCF treatment, which had slightly more runoffand lower K_eff (P < 0.05). Overall, tillage treatments hadno significant effects on soil properties; however, croppingand WT had small significant effects on ${rho}$ _b and K_sat.

Abbreviations: CCF, continuous cultivated fallow • CP, chisel plow • K_eff, effective saturated hydraulic conductivity • K_sat, saturated hydraulic conductivity • MP, moldboard plow • NT, no-tillage • OM, organic matter • USLE, Universal Soil Loss Equation • ${rho}$ _b, bulk density

INTRODUCTION

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

MANY RECOGNIZE THE benefits of conservation tillage for soiland water conservation and for reduced tillage costs. Thereis some concern, however, that long-term use of conservationtillage may not always improve soil properties important forplant growth (Mankin et al., 1996).

Researchers have found that long-term tillage effects on soilproperties such as ${rho}$ _b, soil–water retention, and K_sat oftenvary by soil (Gantzer and Blake, 1978; Culley et al., 1987;Gregorich et al., 1993). For example, moldboard plowing whencompared with chisel plow and no-tillage can lower ${rho}$ _b (Hussain et al., 1998;Katsvairo et al., 2002), leave ${rho}$ _b unchanged (Karlen et al., 1994;Logsdon et al., 1999) or increase ${rho}$ _b (Lal et al., 1994).No-tillage usually has been found to increase ${rho}$ _b comparedwith moldboard and chisel plow (Kitur et al., 1993; Lal, 1999).Bulk density usually is lowest immediately after tillage andincreases with time as a result of rainfall-induced consolidationand surface sealing (Leij et al., 2002). The effects of tillageand management on soil–water retention are also oftenmixed. Allmaras et al. (1977) found no effect on soil–waterretention at greater than –8 kPa, but no-till systemsretained more water than CP systems at lower potentials fora Walla Walla silt loam (Typic Haploxeroll). Tollner et al. (1984)reported that MP resulted in greater soil–waterretention than no-tillage at greater than –80 kPa butnot at other potentials. Conversely, Lal (1999) found that tillagepractices had no significant effect on soil-water retentionat all potentials on a Wooster silt loam (Typic Fragiudalf).Tillage effects on K_sat are even more variable. The K_sat maybe higher, equal, or lower for CP, or MP compared with NT (Gantzer and Blake, 1978;Gregorich et al., 1993; Karlen et al., 1994;Lal, 1999).

These findings suggest the need to improve the understandingof tillage and cropping effects on soil. Reports on long-termtillage effects on soil properties have been reported for anumber of soils (Lindstrom et al., 1981; Blevins et al., 1983;Karlen et al., 1994; Lal, 1999; Rhoton, 2000). However, studiesof tillage effects on properties for midwestern claypan soilsare few. Claypan soils mainly comprise Major Land Resource Area113 in Missouri and Illinois covering about 4 million ha (Ghidey and Alberts, 1998).They are highly erodible and their long-termproductivity is easily degraded by erosion (Gantzer et al., 1990).These soils have an argillic horizon (clay contents >400 g kg^–1) at 130 to 450 mm deep that has very low K_sat(<2 µm h^–1) that often causes large amounts ofsurface runoff during spring (Blanco-Canqui et al., 2002).

Burwell and Kramer (1983), Wendt and Burwell (1985), and Ghidey and Alberts (1998)reported on long-term tillage effects ( $≥$ 10yr) on runoff and soil loss for claypan soils. However, informationon tillage-crop effects on soil properties has not been reported.Research suggests that tillage-crop effects on ${rho}$ _b, soil–waterretention, and K_sat are often soil specific (Culley et al., 1987;Lal et al., 1994; Ankeny et al., 1995). Moreover, it isimportant to document any relationships between soil propertiessuch as K_sat and runoff for these soils. Work relating measuredK_sat to runoff for different tillage treatments is limited (Risse et al., 1995;Blanco-Canqui et al., 2002). Furthermore, theinterrelationships among ${rho}$ _b, OM, soil–water retention,and K_sat induced by long-term tillage-crop management systemsare important and can help development of hydrologic models(Edwards, 1982). Tillage changes in one soil property may causeassociated changes in other soil properties (Culley et al., 1987).

Studies on WT effects on soil properties in long-term tillagesystems for claypan soils are also limited (Lindstrom et al., 1981;Lal, 1999). Traffic compacts soil, and often reduces K_satand increases ${rho}$ _b (Culley et al., 1987). In some cases, trafficmay have little effect (Lindstrom et al., 1981). The size oftraffic-induced changes in soil properties is often site specificdepending on texture, duration of tillage and crop management,equipment, and climate (Lindstrom et al., 1981). A better understandingof long-term tillage-crop systems on soil properties on claypansoils is needed to ensure the best management for these soils.

The objectives of our study are to (i) determine the impactof long-term tillage treatments of NT, CP, and MP under cornand soybean management including a control treatment of CCFon ${rho}$ _b, OM, soil-water retention, and K_sat after 13 yr, (ii) evaluatethe effects of WT, and (iii) determine the possible utilityof using K_sat determined on intact cores for estimating differencesin runoff among the treatments.

MATERIALS AND METHODS

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

This study was conducted on natural runoff-erosion plots locatedat the Midwest Research Claypan Farm (McCredie), Kingdom City,MO. The soil is a Mexico silt loam on a slope of 3%. Runoffplots (3.2 by 27.6 m) were established in 1941, and operatedcontinuously until 1995 to evaluate management effects on surfacerunoff and soil loss for development of the Universal Soil LossEquation (USLE; Wischmeier and Smith, 1978; Ghidey and Alberts, 1998).

In 1981, plots studied in this paper were evaluated for uniformityof soil depth, texture, OM, erosion and runoff. No significantdifferences in these properties were found (Wendt et al., 1986).In 1982, a replicated study was initiated to examine the effectsof NT, CP, and MP planted to corn and soybean, and a CCF (acheck treatment) on runoff and erosion. The study initiallyhad four replicates in a completely randomized block designwith treatments remaining in the same locations over time. Theresults of the study are reported by Ghidey and Alberts (1998).In 1992, two blocks of the 1982 experiment were removed forother uses, resulting in a continuing experiment with seventreatments and two replicates for a total of 14 plots. The CPplots were chiseled twice before planting using a tractor weighing3.6 Mg. Primary and secondary tillage depths were approximately150 and 80 mm, respectively. The MP plots were plowed with a2-bottom plow pulled with a tractor weighing 2.6 Mg a day beforeplanting. Anhydrous ammonia was knifed in to all corn plotsbefore planting. Each plot was planted with a four-row planter.Row spacing was 0.76 m, with rows remaining in the same locationover time. A rear-mounted cultivator on the 2.6-Mg tractor wasused for weed control in CP and MP plots. Wheel traffic fortractor and implements occurred between the first and secondrows and between the third and fourth rows. After grain harvest,cornstalks were chopped and residues left on the soil surface.The CCF treatment was spring moldboard plowed, disked, and cultivatedafter major rainfall events to break soil crusts and to killweeds. Collection of runoff and eroded sediment was terminatedin April 1995, and the soil was left undisturbed for 60 d beforesampling.

Intact 76 by 76 mm diam. soil cores were taken from all plotsin June 1995. Three replicate cores were collected verticallyfrom 0 to 100 and 100 to 200 mm from trafficked and nontraffickedinterrow positions for a total of 168 cores. Cores were takenin an upslope plot position. A double-cylinder, hammer-drivencore sampler was used to collect cores manually to ensure samplingwith minimal disturbance (Blake and Hartge, 1986). Cores weresealed in 2-mil plastic bags, transported to the laboratory,and stored at 4°C for $≤$ 3 d before taking measurements. Sampleswere slowly wet from the bottom with de-aired tap water usinga Mariotte bottle having a supply of approximately 3 mm h^–1increase in head. The EC of the water was 0.68 dS m^–1,and the sodium adsorption ratio (SAR) of the water was 2.34.The K_sat was determined by either the constant- or falling-headmethods where appropriate (Klute and Dirksen, 1986). An 8:1water/bentonite slurry was used to seal macropores ( $≥$ 1 mm diam.)and the interfacial voids between the soil sample and the corecylinder wall to minimize bypass flow. The reason for this wasto eliminate the free flow of water through these voids. Eliminationof bypass flow in small cores during K_sat determinations isa recommended methodology (Klute, 1965; Blanco-Canqui et al., 2002).

The high-energy soil water retention (0 to –16 kPa) wasdetermined on intact cores using Büchner funnels by applyingthe desired pressure, measuring outflow, drying the cores at35°C for 4 d, and recording the oven-dry weight (Gardener, 1986).Because drying soil at 105°C irreversibly alterssoil, samples used for high-energy measurements were dried onlyat 35°C. A 10 g sample of 35°C-dry sample was driedat 105°C to compute its true oven-dry weight for calculationof bulk density of the entire core (Blake and Hartge, 1986).The low-energy soil water retention (–30 to –1500kPa) was determined using a pressure plate apparatus (Gardner,1986). Intact soil slices, 10 mm thick, were saturated in 20by 78 mm rings placed on a ceramic plate for water retentiondeterminations at –30,–100, and –200 kPa.For water retention determinations less than –500 kPa,soil samples were sieved through a 2-mm sieve and packed toa 10-mm depth in rings (Gardner, 1986). Organic matter was determinedby dry combustion using a Leco CR-12 C analyzer (Nelson and Sommers, 1982).Samples for OM were sieved through a 2-mm sieve.Low OM samples were determined on 500-mg samples while highOM samples were determined on 250-mg for samples, and then combustedat 900°C. Organic matter was calculated by dividing theorganic C using a conversion constant of 0.58.

The runoff–K_sat relationship was studied using a K_effof the cores. The K_eff was calculated as

[1]
whereL_T is the total thickness of the 0- to 200-mm depth; L₁, andL₂ are layer thickness values, and K_sat1 and K_sat2 are the K_satvalues for the two depth intervals (0–100 and 100–200mm; Jury et al., 1991). Because trafficked and nontraffickedzones within the plot differed in width, weighted K_eff valuesover traffic positions were computed where the mean K_eff fromthe trafficked or nontrafficked positions was multiplied bythe corresponding width of the trafficked (0.76 m) and nontrafficked(2.44 m) width and divided by the total width (3.2 m) of therunoff plot.

Rainfall and runoff data from 1991 to 1995 collected on a storm-basiswere used to investigate any relationship between runoff andK_eff. Runoff from the 3.2 by 27.6 m plots was collected in aseries of two tanks. When the first tank was filled, runoffthen flowed through a nine-slot divisor and 1/9th of runoffwas then collected in the second tank (Ghidey and Alberts, 1998).The combined tank-series can collect a maximum of 180 mm ofrunoff. After a runoff event, the sediment-runoff mixture volumewas measured and then stirred thoroughly into suspension toobtain three triplicate 1-L samples for sediment concentrationdetermination gravimetrically (Brakensiek et al., 1979). Onlyrunoff data collected from harvest until spring tillage wasused in the analysis to ensure that the soil conditions weresimilar to those of the soil cores collected for K_eff determination.This corresponds with the USLE crop stage Period P4 "Residueor Stubble," (Wischmeier and Smith, 1978). In 1995, runoff measurementsceased in April. Snowmelt runoff and rainfall runoff that occurredon frozen soil were excluded from the study. Snowmelt runoffwas excluded according to the USLE guidelines to evaluate therunoff-K_sat relationship by rainfall-event size. Cumulativerunoff for all storms during Period P4 was calculated and usedto study any relationship with K_eff. In addition, a select groupof medium rainstorms (those between 13 and 54 mm) during PeriodP4 was created from the data that would be expected to reflectthe greatest treatment effect related to soil K_eff. Small rainstorms(<15 mm) produce little or no runoff. For large rainfallevents (>50 mm), rainfall greatly exceeds infiltration capacitydiminishing any differences among treatments to a small fractionof observed runoff, making differences small. Runoff associatedwith these medium rainstorms was summed over the four seasonalperiods (1991-1995) and used in analyzing any relationship betweencumulative runoff and K_eff.

A split-split plot design was used for analysis, with tillageas the main effect, WT as the first split, and depth as thesecond split. Six, single-degree of freedom contrasts, wereused to test differences among tillage and crop treatments.The contrasts were: (i) NT vs. the average of MP and CP [NTvs. (MP + CP)], (ii) MP vs. CP, (iii) Corn vs. Soybean, (iv)an interaction of tillage with crop [NT vs. (MP + CP) x Crop],(v) an interaction of MP vs. CP with crop [(MP vs. CP) x Crop],and (vi) CCF vs. (NT + MP + CP). Computations were done usingSAS statistical software (SAS Institute, 1999). Stepwise regressionwas conducted to evaluate relationships of log K_sat with ${rho}$ _b,OM, and macroporosity (pores that drain at greater than –2kPa of soil–water potential). Mean data were depictedusing box-whisker plots.

RESULTS AND DISCUSSION

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

Bulk Density
Mean ${rho}$ _b values for all treatments, traffic positions, and depthsand the summary of the analysis of variance (ANOVA) are presentedin Table 1. The ${rho}$ _b values averaged across depths for traffickedand nontrafficked zones are given in Fig. 1 . Tillage effectson ${rho}$ _b among NT, CP, and MP were not significant. The small effectsdepended on the crop as shown by the interaction [NT vs. (MP+ CP)] x Crop (P < 0.01; Table 1). The interaction showsthat NT in soybean had a slightly lower ${rho}$ _b (1.47 Mg m^–3)than the average of MP and CP tillage (1.49 Mg m^–3), whereasNT in corn had greater ${rho}$ _b (1.55 Mg m^–3) than the averageof MP and CP (1.52 Mg m^–3; Table 2). The relative higher ${rho}$ _b found in NT corn in this study agrees with an 8-yr tillagestudy that showed higher ${rho}$ _b in NT (1.39 Mg m^–3) than inMP (1.31 Mg m^–3) on a Grantsburg silt loam (Typic Fragiudalf;Hussain et al., 1998). The tillage by crop interaction for ${rho}$ _b[(MP vs. CP) x Crop] was significant (Table 1). The interactionreflects the fact that ${rho}$ _b of MP in corn (1.53 Mg m^–3) wasslightly higher than the ${rho}$ _b of CP (1.50 Mg m^–3), whereasMP in soybean (1.48 Mg m^–3) was slightly lower than CP(1.49 Mg m^–3). The MP in corn was slightly more compactthan CP, but this was not the case for soils under soybean.

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Table 1. Means of bulk density (n = 6) of no-tillage (NT), chisel plow (CP), and moldboard plow (MP) treatments under corn (Zea mays L.) and soybean (Glycine max L.) including a check plot of continuous cultivated fallow (CCF), and analysis of variance of the data.

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Fig. 1. Bulk density of the tillage-crop treatments for trafficked and nontrafficked interrows averaged across both depths of the runoff-erosion plots at the Midwest Claypan Farm near Kingdom City, MO. NT = No-tillage; CP = Chisel plow; MP = Moldboard plow; CCF = Continuous cultivated fallow.

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Table 2. Geometric means of organic matter (n = 6) of no-tillage (NT), chisel plow (CP), and moldboard plow (MP) treatments under corn (Zea mays L.) and soybean (Glycine max L.) including a check plot of continuous cultivated fallow (CCF), and analysis of variance of the data.

Crop grown had a significant effect on ${rho}$ _b (P < 0.01; Table 1).Corn resulted in slightly higher ${rho}$ _b (1.53 Mg m^–3) thansoybean (1.48 Mg m^–3). We speculate that this may be aresult of the differential soil water content at the time ofplanting that influences soil compaction. Less surface residueoccurred with soybeans compared with corn (Gantzer et al., 1987)allowing soil to dry more thoroughly before planting, thus reducingthe potential for compaction. The largest tillage effect occurredfrom the CCF treatment. The CCF averaged across traffic anddepth had the lowest ${rho}$ _b (1.44 Mg m^–3), which was highlysignificant (P < 0.01) as shown in Table 1. This is attributedto the continuous loosening by tillage.

Wheel traffic had a significant effect on ${rho}$ _b (P < 0.01; Table 1).Figure 1 shows that soils under the wheel trafficked interrowhad higher ${rho}$ _b (1.54 Mg m^–3) than nontrafficked interrows(1.45 Mg m^–3). This agrees with results from Vervoort et al. (2001)who found higher ${rho}$ _b (1.49 Mg m^–3) in traffickedvs. nontrafficked zones (1.43 Mg m^–3) on a Grenada siltloam (Oxyaquic Fraglossudalfs). Another study on a Capac loam(Aeric Ochraqualfs) reported that WT increased ${rho}$ _b by 29% in tilledsoils (Pierce et al., 1994). The higher ${rho}$ _b in trafficked positionsimplies soil consolidation and reduction of macropores resultingin decreased soil porosity; however, it is not likely to reduceplant root growth as it is below the growth limiting value of ${rho}$ _b (1.55 Mg m^–3; Radcliffe et al., 1988).

The depth effect on ${rho}$ _b was significant (P < 0.01; Table 2).The ${rho}$ _b at the 0- to 100-mm depth was lower (1.47 Mg m^–3)than at the 100- to 200-mm depth (1.52 Mg m^–3) for alltreatments. Lower ${rho}$ _b at the upper depth is commonly due to thegreater amounts of organic material near the surface, loweroverburden pressure, and greater disturbance. The increase of ${rho}$ _b with depth is consistent with a study on a Maury silt loamsoil (Typic Paleudalfs) by Ismail et al. (1994) who showed that ${rho}$ _b under NT and MP in corn decreased with depth after 20-yr oftillage.

Our results show that tillage effects on ${rho}$ _b were small; however,crop had a significant effect where corn increased ${rho}$ _b comparedwith soybean. Differences in ${rho}$ _b among NT, CP, and MP were notsignificant and would not limit crop production.

Organic Matter
Geometric means of OM values and the ANOVA summary are shownin Table 2. Values for all treatment-depths averaged acrosstraffic are presented in Fig. 2 . Normality tests showed thatOM data were nonnormally distributed (P < 0.01). Since alogarithmic transformation improved the normality, statisticswere conducted on log-transformed OM data. The tillage by cropcontrast of NT vs. the average of CP and MP and the interaction[NT vs. (MP + CP)] x Crop was significant (P < 0.04; Table 2).The interaction of tillage treatments with crop is illustratedby the fact that NT in corn (19.3 g kg^–1) had higher OMthan the average of the MP and CP treatments (14.8 g kg^–1),but not in soils under soybean. The greater amount of corn residuesin NT increased OM content in contrast with soils in soybean.The higher OM in NT corn agrees with studies conducted for othersilt loam soils. Blevins et al. (1983) reported that after 10-yrof continuous tillage, NT in corn had higher OM content (47g kg^–1) than MP (24 g kg^–1) on a Maury silt loam(Typic Paleudalfs). After 4-yr tillage, Rhoton (2000) also showedthat NT soils in corn had higher OM (32 g kg^–1) than MPsoils (19.1 g kg^–1) at the 0- to 25-mm depth on a Grenadasilt loam (Glossic Fragiudalfs). The higher OM content in NTcorn (19.3 g kg^–1) is a result of corn residue near thesoil surface. In contrast, inverted crop residues in MP treatmentsare mixed throughout the depth of tillage.

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Fig. 2. Geometric means of organic matter of the tillage-crop treatments for the 0- to 100- and 100- to 200-mm depths averaged across traffic for the runoff-erosion plots at the Midwest Claypan Farm near Kingdom City, MO. NT = No-tillage; CP = Chisel plow; MP = Moldboard plow; CCF = Continuous cultivated fallow.

Crop had no significant effect on OM (P = 0.07; Table 2). Organicmatter in corn averaged across tillage, traffic, and depth (16.3g kg^–1) was slightly higher than in soybean (14.5 g kg^–1).Corn is a high biomass-crop resulting in increased OM contentcompared with soybean. Greater OM in corn may also be attributedto a lower rate of corn residue decomposition than for soybeanresidues (Broder and Wagner, 1988). The major effect of long-termtillage occurred for the CCF treatment. The CCF had the lowestOM (9.8 g kg^–1) of all treatments (15.3 g kg^–1)averaged across traffic and depth, which was highly significant(P < 0.01). Results indicate that excessive cultivation leadsto significant decline of OM in accord with Cambardella and Elliot (1992)who reported that OM in NT was 1.4 times higherthan in bare-fallow soil after 20-yr tillage on a Duroc loam(Pachic Haplustolls).

Wheel traffic had no effect on OM (Table 2). As expected, WTwould not significantly affect OM (Pierce et al., 1994; Lal, 1999).The OM distribution was significantly influenced by depth(P < 0.01; Table 2). The OM averaged across tillage-cropand traffic at the 0- to 100-mm depth (15.5 g kg^–1) wassignificantly higher than at the 100- to 200-mm depth (14.0g kg^–1). This is caused by the greater concentration ofOM near the soil surface (Pierce et al., 1994; Rhoton, 2000).

Soil–Water Retention
Soil–water retention data averaged across crop, WT, anddepth for all treatments are given in Fig. 3A , and soil–waterretention data for trafficked and nontrafficked zones in CCFare presented in Fig. 3B. Analysis of variance results for –4kPa are given in Table 3. Because differences were greater athigh-energy potentials, only data greater than –100 kPaare plotted in Fig. 3. Tillage and cropping effects on soil–waterretention among NT, CP, and MP were not significant. In contrast,tillage effects on CCF were significant (P < 0.05). Comparisonof regression lines in Fig. 3A between CCF and the average ofNT, CP, and MP treatments using analysis of covariance showedthat the slopes of the lines were not significantly different(P > 0.07) and the elevations of the regression lines differed(P < 0.05; Snedecor and Cochran, 1989). Results indicatedthat CCF retained more water than the average of NT, CP, andMP at high-energy soil–water potentials (P < 0.01).The water content for CCF was approximately 4% higher at –1kPa and approximately 2% higher at –100 kPa as comparedwith the average for NT, CP, and MP (Fig. 3A). Continuous cultivationincreases fine pores, lowers OM content, and destroys macropores(Jordan et al., 1997; Hussain et al., 1998).

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Fig. 3. Soil–water retention of (A) the tillage-crop treatments averaged across crop, traffic, and depth, and (B) trafficked and nontrafficked positions averaged across depth in CCF for the runoff-erosion plots at the Midwest Claypan Farm near Kingdom City, MO. NT = No-tillage; CP = Chisel plow; MP = Moldboard plow; CCF = Continuous cultivated fallow.

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Table 3. Geometric means of saturated hydraulic conductivity (K_sat) (n = 6) for no-tillage (NT), chisel plow (CP), moldboard plow (MP) treatments under corn and soybean including a check plot of continuous cultivated fallow (CCF), and analysis of variance of K_sat and soil-water retention (SWR) data.

Wheel traffic had no effect on soil–water retention amongNT, CP, and MP, but there was a significant effect on CCF treatmentat most potentials (P < 0.05). Analysis of covariance ofthe regression lines for trafficked and nontrafficked positionsfor CCF in Fig. 3B showed that the slopes of the lines werenot significantly different (P > 0.10) but differed in elevationsof the regression lines (P < 0.01). These results thus showthat water retention in CCF in trafficked interrows was higherthan in nontrafficked interrows at high-energy soil–waterpotentials. The combined effect of tillage and decrease in largewater conducting macropores increased the water retention intrafficked CCF, which is in agreement with Culley et al. (1987)who also found greater soil–water retention in traffickedzones than nontrafficked zones from –0.5 to –6 kPaon a Webster silty clay loam (Typic Haplaquoll).

Depth had a significant effect on soil–water retentiononly at –4 (P < 0.01) and –1.5 MPa (P < 0.05)of soil–water potential. Mean water content averaged acrosstillage-crop and traffic was 0.36 mm mm^–3 at the 0- to100-mm depth and 0.39 mm mm^–3 at the 100- to 200-mm depthfor the –4 kPa, while the averaged values for the –1.5MPa were 0.12 mm mm^–3 at the 0- to 100-mm depth and 0.14mm mm^–3 at the 100- to 200-mm depth. The greater soil–waterretention at the lower depth may be due to higher proportionof micropores and more compaction compared with the upper depths(Radcliffe et al., 1988). Overall, the effects of tillage-crop,WT, and depth on soil–water retention were small, anddifferences were not significant in most cases except for CCFthat retained the highest amount of water of all treatmentsfor high energy soil–water potential.

Saturated Hydraulic Conductivity
Geometric means of K_sat and the related ANOVA summary are presentedin Table 3. The geometric mean K_sat values averaged across depthfor trafficked and nontrafficked positions are presented asa box-whisker plot in Fig. 4 . Data were found to be significantlynonnormal (P < 0.01). Therefore, statistical analysis wasperformed on log-transformed values. No differences were foundfor the single-df contrast of NT vs. (CP and MP) averaged acrosstraffic, depth, and crop (P = 0.57).

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Fig. 4. Geometric means of saturated hydraulic conductivity (K_sat) of the tillage-crop treatments for trafficked and nontrafficked interrows averaged across depths for the runoff-erosion plots at the Midwest Claypan Farm near Kingdom City, MO. NT = No-tillage; CP = Chisel plow; MP = Moldboard plow; CCF = Continuous cultivated fallow.

Our results indicate that the tillage effects on K_sat are small.The naturally compacted soil in NT did not reduce K_sat (Table 3).The effects of long-term tillage are similar to resultsby Blevins et al. (1983) who found no differences in K_sat betweenNT and MP on a Maury silt loam after 10-yr of tillage, and withGregorich et al. (1993) who reported that K_sat did not differbetween no-till and tilled soils on a poorly drained clay loamsoil (Aquoll) after 20-yr of tillage. These findings, also agreewith results reported on a Le Sueur clay loam (Aquic Argiudoll)soil having 28% clay-size particles by Gantzer and Blake (1978).

The type of crop grown had a significant effect on K_sat (P <0.01; Table 3). The K_sat under soybean management (11.7 mm h^–1)was 1.6 times higher than under corn management (7.3 mm h^–1).The K_sat differences may be partially explained by the lower ${rho}$ _b in soybean and higher ${rho}$ _b in corn. The K_sat was negatively correlatedwith ${rho}$ _b (r = –0.54, P < 0.05). Mankin et al. (1996),while investigating the cropping effects on soil propertiesin the major corn and soybean production regions in the USA,found higher K_sat in soybean than in corn particularly in claysoils. While crop residue from soybean is only about 50% ofthat from corn, soybean residues have a greater proportion ofsoluble compounds, lower cellulose, and are more easily decomposedinto humidified organic compounds interacting with soil particlesand probably improving soil aggregation and water infiltration(Broder and Wagner, 1988).

The K_sat for CCF was five times lower (1.9 mm h^–1; P <0.01) than the average of the other treatments (9.5 mm h^–1).This lower K_sat reflects the impact of frequent cultivationon reducing the OM, and thus deteriorating soil aggregationand destroying macropores (Radcliffe et al., 1988; Jordan et al., 1997).Because of the lower K_sat, less infiltration andhigher runoff are expected from CCF management compared withNT, CP, and MP tillage.

Wheel traffic reduced K_sat in all tillage treatments (P <0.01). Figure 4 shows that K_sat in nontrafficked zones averagedacross tillage, crop, and depth was 3.1 times higher (14.3 mmh^–1) than K_sat in trafficked zones (4.4 mm h^–1).The higher K_sat values in nontrafficked positions are in accordwith Culley et al. (1987) who found that nontrafficked K_satwas nine times higher than trafficked K_sat on a Webster siltyclay loam. The reduction of K_sat from equipment traffic is causedprimarily by soil surface consolidation associated with increasedbulk density and reduced soil porosity. Lindstrom et al. (1981)on a Nicollet clay loam (Aquic Hapludolls) found that WT reducesthe random roughness of the soil surface and compacts the plowlayer resulting in decreased water infiltration rates.

In general, the K_sat did not vary significantly with depth (Table 3).The K_sat averaged across tillage, crop, and traffic was9.4 mm h^–1 in the 0- to 100-mm depth, and 9.2 mm h^–1in the 100- to 200-mm depth. Our results agree with Lal (1999)who found no K_sat differences with depth under NT, CP, and MPmanagement after 5-yr tillage in Ohio. Unlike ${rho}$ _b, the K_sat distributionwith depth did not change significantly.

Effects of 13-yr continuous tillage management on K_sat werefor the most part small, but cropping system had a significanteffect on K_sat. The nonsignificant changes in K_sat found inthis study suggest that long-term NT, CP, and MP managementin claypan soils would not be expected to affect crop production.The main finding was that the CCF treatment reduced K_sat byfive times (P < 0.01).

Interrelationships of Soil Properties
Investigation of relationships of log K_sat with ${rho}$ _b, OM, and macroporosityamong NT, CP, and MP treatments using regression showed that ${rho}$ _b was the only significant variable related with log K_sat. Therelationship found was:

The intercept and the slope for the NT, CP, and MP treatmentswere significant at P < 0.01. The negative slope impliesthat the conductivity would decrease with increasing ${rho}$ _b. Theability for ${rho}$ _b to predict log K_sat in NT, CP, and MP treatmentsis corroborated by work of Edwards (1982). However, it was foundthat the regression of ${rho}$ _b on log K_sat for the CCF treatment wasnot significant (P > 0.10). Despite the fact that this treatmenthad lower bulk densities, the conductivities were often thelowest. The fact that ${rho}$ _b was not significantly related to conductivityfor the CCF is at odds with knowledge that low ${rho}$ _b is often relatedto increased K_sat. We attribute this behavior to structuralinstability of soil aggregates in the CCF treatment due to intensivecultivation, which decreased OM, and weakened soil aggregates.On wetting, aggregates slump, causing decreased pore continuity,thus lowering K_sat. Overall, macroporosity was highly correlatedwith ${rho}$ _b (r = –0.83) and moderately correlated with conductivityfor all treatments (r = 0.44). An interesting finding is that ${rho}$ _b and K_sat in the CCF treatment were the lowest of all tillage-croptreatments. In contrast, NT, CP, and MP management had no significantdifferences in ${rho}$ _b and K_sat.

Runoff–K_eff Relationship
The graphs of cumulative runoff versus log K_eff for the tillage-croptreatments in January through April 1995 and during the PeriodP4 in 1991 through 1995 are depicted in Fig. 5 . The runoff–K_efflinear regression using cumulative runoff data from Januaryto April of 1995 where soil conditions would be nearly the sameas those during our soil sampling date (14 June 1995) showedno relationship between runoff and K_eff (r² = 0.01). In additionto the above analysis, an investigation of a longer-term runoff–K_effregression was conducted using cumulative runoff data from 1991through 1995. The linear regression indicated that K_eff wasnot related to runoff from NT, CP, and MP under corn and soybeanfor all runoff events and rainfall storm sizes between 1991through 1995 (r² = 0.10). For medium rainstorms (between 13and 54 mm), the linear regression r² increased but was not significant(r² = 0.15; Fig. 5).

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Fig. 5. Relationship between cumulative runoff and log of the effective saturated hydraulic conductivity (K_eff) for all rainstorms in January through April 1995 and for the Universal Soil Loss Equation (USLE) crop stage period "P4 Residue or Stubble," for medium rainstorms (between 13 and 54 mm) from 1991 to 1995. NTC = No-tillage in corn (Zea mays L.); CPC = Chisel plow in corn; MP = Moldboard plow in corn; NTS = No-tillage in soybean (Glycine max L.); CPS = Chisel plow in soybean; MPS = Moldboard plow in soybean; CCF = Continuous cultivated fallow.

Results showed that the runoff vs. K_eff relationship was highlyinfluenced by higher runoff produced in the CCF treatment, whichwas 36% more than the next highest runoff amount found in otherplots (P < 0.01). The highest runoff for the CCF treatmentwas probably a result of surface sealing of the bare soils inhibitingwater infiltration and thus increasing runoff. Our results indicatethat K_eff values from continuously tilled soils are relatedto runoff suggesting that K_eff can be a significant predictorof runoff only for excessively tilled soils. This is supportedby Bruce et al. (1992) who concluded excessive tillage leadsto low K_sat and increased runoff.

The limited relationship between runoff vs. K_eff in NT, CP,and MP agrees with Edwards (1982) who reported that K_sat isnot as sensitive a variable as precipitation, and antecedentsoil moisture for predicting runoff. The reasons for the limitedrelationship in this study may be attributed to (i) temporalvariability of K_eff in tillage systems, and (ii) low claypanconductivity. The dynamic temporal variability of tilled soilsmay create difficulties in establishing a surface runoff vs.K_eff relationship. The K_eff may be more related to runoff immediatelyafter tillage when differences in surface physical propertiesbetween tilled and no-till soils are great. Tillage loosensthe soil and creates unstable structure increasing the K_effand reducing runoff after tillage relative to no-tillage thatremains consolidated over time. However, tillage effects onsoil surface conditions dissipate rapidly with time as externalforces (traffic, overburden pressure, rainfall-induced consolidation,and surface sealing) take place. Tilled soils may thus be physicallysimilar to no-till, as the residual effects of tillage diminishwithin 21 to 28 d. Or et al. (2000) and Leij et al. (2002) affirmedthat soil immediately after tillage is highly unstable and undergoesdynamic changes in the interaggregate porosity significantlyaltering the hydraulic properties. The K_sat after plowing canbe one or two orders of magnitude higher compared with K_satmeasured before tillage. Such K_sat changes diminish with timeas the natural structural pore system gradually evolves. Oursoil samples were collected almost a year after primary tillage,and thus differences in initial soil conditions among NT, CP,and MP would have diminished.

An understanding of the K_eff variations by crop-stage period,and seasonal variations induced by management would be desirable.An important factor reducing differences in runoff among treatmentsis related to the claypan soil that has a nearly impermeableclaypan at approximately 230 mm (K_sat $≤$ 0.003 mm h^–1).The low claypan K_sat limits downward water movement and redirectsthe flow laterally into interflow (Blanco-Canqui et al., 2002).Indeed, runoff rates are equal to precipitation when these soilsare saturated particularly in spring (Saxton and Whitaker, 1970).Thus, claypan K_sat is the main control that inhibits verticalwater flow. This would be expected to have a significant influenceon the surface runoff vs. K_eff relationship. Assessment of soilparameters that are sensitive to tillage and crop managementchanges in soil structure such as least limiting water rangemay help to evaluate tillage management impact effects on hydraulicproperties (Da Silva et al., 1994).

CONCLUSIONS

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

This 13-yr study on the effects of tillage-crop management onsoil physical properties for an Aeric Epiaqualf shows that onlysmall changes in ${rho}$ _b, OM, soil–water retention, and K_satoccurred from the NT, CP, and MP treatment under corn and soybeanmanagement. Results suggest that the tillage systems are oflittle importance to soil properties in claypan soils, and thuswould not greatly affect crop production. However, the CCF treatmenthad a major effect on soil properties decreasing K_sat, ${rho}$ _b, andOM in contrast to NT, CP, and MP. This confirms the idea thatexcessive tillage has a deleterious effect on soil properties.

The kind of crop (corn vs. soybean) had a greater effect onsoil properties compared to tillage. Soils in corn had decreasedK_sat, and increased ${rho}$ _b and OM as compared with soils in soybean.Increased compactness of soils in corn may significantly reducesaturated water flow while increasing OM in claypan soils. TractorWT caused soil consolidation and reduced saturated water flow.No consistent relationship between runoff and effective K_satfor NT, CP, and MP treatments was identified. Thus, K_sat determinedon small intact cores was not a significant predictor of runoff.However, runoff from excessively tilled plots (CCF) was relatedto effective K_sat where runoff increased. The ${rho}$ _b was a significantpredictor of log K_sat for NT, CP, and MP but not in CCF becauseof excessive soil disturbance that lowered K_sat, ${rho}$ _b, and OM.While conservation tillage is beneficial for soil and waterconservation and for reduced tillage costs, changes in topsoilphysical properties due to conservation tillage management aresmall.

ACKNOWLEDGMENTS

This study was supported in part by the MO Agric. Exp. Stn.Proj. #260, the Missouri Water Resour. Res. Center (U.S. Dep.of the Interior), the Latin American Scholarship Program ofAmerican Universities (LASPAU)-Fulbright Program, and by theUSDA-ARS Cropping Systems and Water Quality Res. Unit.

NOTES

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

Contribution of Missouri Agric. Exp. Stn. Proj. #260.

Received for publication April 29, 2003.

REFERENCES

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

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