Short-Term Effects of Land Leveling on Soil Chemical Properties and Their Relationships with Microbial Biomass

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DIVISION S-6—SOIL & WATER MANAGEMENT & CONSERVATION

Short-Term Effects of Land Leveling on Soil Chemical Properties and Their Relationships with Microbial Biomass

K. R. Brye^*^,a, N. A. Slaton^a, M. Mozaffari^b, M. C. Savin^a, R. J. Norman^a and D. M. Miller^a

^a Dep. of Crop, Soil, and Environmental Sciences, Univ. of Arkansas, 115 Plant Sciences Building, Fayetteville, AR 72701
^b Dep. of Crop, Soil, and Environmental Sciences, Univ. of Arkansas, P.O. Drawer 767, Marianna, AR 72360

^* Corresponding author (kbrye{at}uark.edu).

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Spatial variability and distributions of soil chemical propertiesand the relationships between soil chemical and biological propertiesare not well characterized in agroecosystems that have beenland leveled to facilitate more uniform delivery of irrigationwater. The objectives of this study were to characterize theshort-term impacts of land leveling on the magnitudes, spatialvariability, and spatial distributions of soil chemical propertiesand to evaluate the impact of land leveling on the relationshipsbetween soil chemical properties and microbial biomass in aStuttgart silt loam (fine, smectitic, thermic Albaqultic Hapludalf)used for irrigated soybean [Glycine max (L.) Merr.] and rice(Oryza sativa L.) production in the Mississippi Delta regionof eastern Arkansas. A grid-sampling approach was used to characterizepre- and postleveling soil chemical properties and microbialbiomass. Results of this study demonstrate that land leveling,a severe form of anthropogenic soil disturbance, causes significantalteration of the magnitudes, spatial variability, and spatialdistributions of many soil chemical properties. Soil electricalconductivity (EC) and the contents of P, K, Mg, Na, S, Mn, andCu in the top 10 cm significantly increased, while soil pH andorganic matter (OM) and Fe contents significantly decreased,as a result of land leveling. Land leveling also significantlyaltered many linear relationships among soil chemical propertiesand microbial biomass. The benefit of improved water distributionmust be weighed against the relatively severe and immediatealteration of soil properties and natural processes broughton by land leveling. Further research is required to ascertainlong-term effects of altered soil biogeochemical propertieson crop growth as a result of land leveling.

Abbreviations: EC, electrical conductivity • FDA, fluorescein diacetate • OM, organic matter

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

IN THE RECENT Farm Bill, the U. S. Congress reauthorized substantialfinancial assistance in the form of government subsidies tofarmers willing to adopt water conservation practices (USDA, 2002).Land leveling, a relatively common agricultural practicein the south-central USA in recent decades could be considereda water conservation practice. Land leveling creates a slight,but uniform, slope gradient to facilitate more even distributionof irrigation water and is routinely performed in fields wherecrops such as rice and soybean are grown. Passing of the 2002U.S. Farm Bill could significantly impact the number of farmerswho choose to have a field land leveled due to the substantialgovernmental support they could possibly receive. Therefore,ascertaining the degree to which soil properties change, bothin magnitude and spatially, and how a subsequent crop will respondto altered and potentially more variable soil properties willimprove management capabilities to ensure maximum or near-maximumproduction from graded fields.

The potential agronomic benefits of land leveling have beenrecognized for more than half a century and include improveddistribution of irrigation waters, soil and water conservation,and improved uniformity of crop growth and yield within a field(Whitney et al., 1950). However, the positive effects of landleveling on crop production are equally as numerous as the negativeeffects of growing crops in exposed subsoil. Deficiencies inessential plant nutrients (e.g., N and P) can limit crop growthfollowing land leveling (Whitney et al., 1950; Eck, 1987; Robbins et al., 1997,1999). Exposing subsoil can result in major changesin soil surface pH, decreased organic C, and Na toxicity (Miller, 1990).Miller (1990) also speculated that the near-surface spatialvariability of certain soil properties in eastern-Arkansas soilscropped to rice was affected by land leveling and that thisvariability was related to postleveling variability in cropgrowth. Similarly, spatial variability of soil properties hasbeen implicated in nonuniform growth of tropical lowland ricein the Philippines (Dobermann et al., 1995, 1997).

In eastern Arkansas, where approximately 40% of the total riceproduction in the USA occurs (National Agricultural StatisticsService [NASS], 2001), rice yields have been shown to increaseon land-leveled fields when fertilized with inorganic N, P,and Zn and/or amended with composted and uncomposted poultrylitter (Miller et al., 1990, 1991). In contrast, fertilizationwith inorganic K and/or S did not significantly affect riceyields on land-leveled soil (Miller et al., 1990). These studiesindicated that land leveling caused decreased contents of soilorganic C, N, P, and Zn, but not K or S. In addition to affectingyield, changes in soil chemical properties as a result of landleveling may also impact soil biology.

Spatial distributions of soil microbial biomass, especiallyfungi and bacteria, are still not completely understood in terrestrialecosystems (Parkin, 1993), especially in agroecosystems usingvarious tillage practices (Wardle, 1995). Soil microorganismsare important for maintaining soil quality due to their rolein decomposition of OM and nutrient cycling and storage, andpotentially represent a very sensitive biological marker (Turco et al., 1994).To our knowledge, few studies have characterizedthe effects of land leveling on soil biological properties.Soil biological properties are intimately related to the chemicalenvironment in the soil and are as important in controllingsoil tilth as soil chemical and physical properties. In general,the microbial community in agroecosystems is poorly understoodand not well characterized (Parkin, 1993; Wardle, 1995). Sincethe combined populations of fungi and bacteria represent a largefraction of the total soil microbial biomass, changes in landmanagement or disturbance of the soil profile from land levelingwould likely affect the populations or population ratio of thesoil fungal and bacterial communities (Bardgett et al., 1996;Brye et al., 2003) and the chemical properties that controltheir existence.

The objectives of this study were to (i) characterize the short-termimpacts of land leveling on the magnitudes, spatial variability,and spatial distributions of soil chemical properties, and ii)evaluate the impact of land leveling on the relationships amongselected soil chemical properties and between soil chemicaland microbial biomass in a soil of the Mississippi Delta regionin eastern Arkansas commonly used for irrigated rice and soybeanproduction. We hypothesized that land leveling significantlyalters the magnitude, spatial variability, and distributionof soil macro- and micronutrients. We also hypothesized thatland leveling significantly affects the relationships betweenmicrobial biomass, soil pH, and OM and between extractable soilnutrient contents, soil pH, EC, and OM content.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Site Description
The study area was located within a 5-ha land leveled area ofa 25-ha field predominantly cropped to rice and soybean in ArkansasCounty, AR (34° 6' N, 91° 22' W). The soil was a Stuttgartsilt loam, which was originally classified as a fine, montmorillonitic,thermic, Typic Natrudalf (Maxwell et al., 1972), but has beensubsequently reclassified as a fine, smectitic, thermic AlbaqulticHapludalf (Soil Survey Division [SSD], 2002). The Stuttgartseries formed in silty and clayey alluvium and is a very deep,moderately well to somewhat poorly drained, slowly permeablesoil. During the growing season before land leveling, the fieldcontaining the study area was in rice production and up untilthe land leveling occurred was gently rolling with a 1 to 2%slope.

Experimental Design
Before land leveling, a 40 by 90 m sampling grid (0.36 ha) wasestablished as the study area within approximately 5 ha thatwas to be land leveled (i.e., manipulated). Grid points (i.e.,sampling points) were spaced evenly at 10-m apart, for a totalof 50 grid points, to facilitate statistical evaluation of theeffects of land leveling on the magnitude, variability, andspatial distribution associated with soil chemical and microbialbiomass. The grid was positioned in the field so that roughlyone-half of the sampling area was cut (i.e., topsoil was scrappedand removed from an area of relatively high elevation) and theother half was filled (i.e., deposition into an area of relativelylow elevation of soil previously scrapped and removed from anotherarea within the same field).

Study Site Manipulations
Land leveling occurred at the site in April 2002 resulting ina uniform slope throughout the study area. After initial cuttingand filling occurred, the entire manipulated area was regradedto eliminate minor topographic variations. During the regradingprocess, some material originally removed from the cut areawas pushed from the filled area back onto the cut area. Themaximum depth of cut was roughly 15 cm. Within 2 wk followingland leveling, semi-solid composted poultry litter was broadcastat approximately 2.2 Mg ha^–1 throughout the entire studyarea using a tractor-drawn manure spreader as recommended bythe University of Arkansas Cooperative Extension Service (Slaton, 2001).The poultry litter application so soon after completionof the land-leveling activity was the result of miscommunicationwith the cooperating landowner and was not originally intendedto be part of the experimental design of this study. However,in general, composted poultry litter from northwest Arkansashas a pH of 8.0 to 8.7, and contains 257 to 302 g total C kg^–1,35 to 39 g total N kg^–1 (fresh-weight basis), 1.6 to 3.0g soluble reactive P kg^–1, 31 to 35 g total P kg^–1,and approximately 36 g total N kg^–1 (dry-weight basis)(DeLaune, 1999). These concentrations and contents are similarto the chemical composition of other sources of composted poultrylitter in the southeastern USA (Tyson and Cabrera, 1993; Warren and Fonteno, 1993;Freeman and Cawthon, 1999). In addition,Warren and Fonteno (1993) indicate that composted poultry litterhas a total porosity of approximately 78% and a bulk densityof approximately 0.5 Mg m^–3.

Sampling Scheme and Measurements
On 11 Jan. (i.e., preleveling) and 9 May 2002 (i.e., postleveling),soil samples were collected for chemical (i.e., extractablenutrients, pH, EC, and OM) and biological (i.e., fungal andbacterial biomass concentrations) property determination. Novegetation existed in the study area between sampling dates.Postleveling samples were collected only 1 wk after poultrylitter application, with no significant precipitation eventsbetween litter application and postleveling soil sampling, andthe litter was physically scrapped aside from each sample locationso that it was not included in the actual sample.

A single 4.8-cm diameter soil core (the soil-core sampling chamberwas beveled to the outside to minimize compaction upon sampling)was collected from the 0- to 10-cm depth within a 20-cm radiussurrounding each grid point, oven dried at 70°C for 48 h,and weighed for bulk density determination. Ten 2-cm diametersoil cores were collected from the 0- to 10-cm depth withina 20-cm radius surrounding each grid point and composited, ovendried at 70°C for 48 h, crushed, and sieved to pass a 2-mmmesh screen for soil chemical analyses. Dried and sieved soilwas extracted with Mehlich-3 extractant solution (Tucker, 1992)in a 1:10 soil/extractant solution ratio and analyzed for extractablenutrients (i.e., P, K, Ca, Mg, Na, S, Fe, Mn, Zn, Cu, and B)using an inductively coupled argon-plasma spectrophotometer(CIROS CCD model, Spectro Analytical Instruments, MA). SoilpH and EC were determined with an electrode on a 1:2 soil/watersolution. Organic matter was determined on sieved soil by weight-loss-on-ignitionafter 2 h at 360°C (Schulte and Hopkins, 1996). A secondset of ten 2-cm diameter soil cores were also collected fromthe 0- to 10-cm depth within a 20-cm radius surrounding eachgrid point and composited for biological assays. These sampleswere immediately iced in the field then refrigerated <3 dbefore fungal and bacterial biomass determinations were conducted.

Total fungal biomass was determined using methods describedby Ingham and Klein (1984). For each sample, a suspension wasprepared from fresh soil mixed with 90 mL of 60 mM phosphatebuffer (pH 7.6). One-milliliter aliquots were removed, stainedfor 3 min with 1 mL of 20 µg mL^–1 fluorescein diacetate(FDA) solution in 60 mM phosphate buffer, and filtered. Onemilliliter of 1.5% (v/v) agar in distilled water was added toa 1-mL FDA suspension in phosphate buffer and mixed. An aliquotwas placed on a microscope slide of known dimensions. Totalfungal biomass was estimated from stained hyphal lengths anddiameters determined by direct microscopic examination of thesoil–agar film in three transects of 20 fields per slideusing phase-contrast microscopy.

Total bacterial biomass was determined using methods describedby Babiuk and Paul (1970). Twenty grams of fresh soil were mixedwith 190 mL of sterile distilled water and shaken for 2 min.Aliquots of the suspension were placed within a 1-cm² area ofa microscope slide, allowed to air dry, and slightly fixed withheat. Soil smears were stained with fluorescein isothiocyanatefor 2 min and washed. Stained soil smears were immediately mountedin glycerol and observed using phase-contrast microscopy. Totalbacterial biomass was estimated from the number of bacteriaand their mean diameter and length per field.

Data Manipulation and Statistical Analyses
Extractable soil nutrient and microbial biomass concentrations,expressed on a mass per mass basis, and bulk density were usedto calculate extractable nutrient and microbial biomass contents,expressed on a mass per area basis. Soil chemical propertiesare reported as mean values (±standard error [SE]). Coefficientsof variation (CV) were also calculated for soil chemical properties.

Although the sampling grid was positioned such that approximatelyone-half of the area was cut and one-half of the area was filled,the regrading process that occurred following initial site manipulationscaused the entire study area to have some degree of fill material.Therefore, the roughly cut and filled areas were not treatedas experimental treatments and were not separated during statisticalanalyses.

Without true replication, but rather pseudo-replication in time,paired t tests were performed, retaining the identity of eachsampling point, to determine the short-term effects of landleveling on extractable soil nutrient contents, pH, EC, andOM (Minitab 13.31, Minitab Inc., State College, PA). Soil moisturewas above field capacity and near saturation on both sampledates; therefore water content was not considered a variablethat affected pre- and postleveling comparisons. Pearson linearcorrelations were performed to ascertain correlations amongselected soil chemical properties, between microbial biomassand soil pH, EC, and OM, and whether significant correlationsdetermined before land leveling changed due to land leveling.Based on significant correlations, linear and multiple regressionanalyses were used to determine the relationships among selectedsoil chemical properties and between soil chemical propertiesand fungal and bacterial biomass contents. Analysis of covariancewas used to determine if the slope and/or intercept differedbetween pre- and postleveling linear relationships (SAS Version8.1, SAS Institute, Inc., Cary, NC).

The effects of land leveling on the spatial variability of soilchemical properties were determined by several methods. Homogeneityof variance was evaluated using Levene's test (Levene, 1960).Geostatistical analyses were also conducted using GS+ (version5.1, Gamma Design Software, Plainwell, MI). Only isotropic semivariogramswere considered and semivariance parameters for spherical, exponential,or linear models are reported for pre- and postleveling pH,EC, OM, and extractable soil nutrient contents.

The effects of land leveling on the spatial distributions ofsoil chemical properties were determined by mapping pre- andpostleveling pH, EC, OM, and extractable soil nutrient contentsusing Surfer 7 (Golden Software, Inc., Golden, CO). Point krigingwith no search radius was used as an unbiased, weighted linearinterpolation method that minimizes total parameter varianceby incorporating semivariogram functions to create contour maps(Isaaks and Srivastava, 1989). Only the linear semivariogramfunction for all parameters was used to facilitate mapping andcomparisons among soil chemical properties.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Soil Chemical Properties
Land leveling significantly affected (P < 0.05) soil pH,EC, OM content, and the contents of all extractable soil nutrientsexcept for Ca, Zn, and B (Table 1). Soil EC and the contentsof P, K, Mg, Na, S, Mn, and Cu in the top 10 cm increased significantly(P < 0.05) as a result of land leveling. In contrast, soilpH and OM and Fe contents in the top 10 cm decreased significantly(P < 0.01).

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Table 1. Effect of land leveling on soil chemical properties and microbial biomass from the 0- to 10-cm depth. Mean values (±standard error) are reported with the change in coefficient of variation ( ${Delta}$ CV) of pre- to postleveling soil properties [(CV_post – CV_pre)/CV_pre x 100]. Asterisks next to postleveling means represent significant pre- and postleveling differences.

Significant changes in soil pH can adversely or beneficiallyinfluence the growth and production of both rice and soybeanbecause soil pH influences the availability of several essentialelements. Phosphorus and Zn are common yield-limiting factorsfor rice grown on eastern Arkansas silt-loam soils made alkalinefrom the use of high carbonate-containing irrigation water,and their availability generally decreases as soil pH increases(Norman et al., 2003). Conversely, N fixation by soybeans ismost efficient when the soil pH is between 5.5 and 6.8 (Mengal et al., 1987).Although soil pH declined after land leveling,the average 0.3 unit pH decline would not likely be agronomicallysignificant unless the content of plant available nutrientsalso declined significantly. Soils that have been irrigatedwith ground water high in Ca and Mg bicarbonates for many yearstypically have soil pH > 7.0 to a depth of 20 to 30 cm (Thomas, 2001).Depending on how soil chemical properties change withincreasing soil depth and the depth of cutting, the potentialexists for land-leveling procedures to expose acidic or sodicsubsoils that could contribute to nutrient availability disorderssuch as Al toxicity, sodicity, and micronutrient deficienciesand toxicities (Tisdale et al., 1993; Daniels et al., 2002).The cuts made on this field were relatively shallow (approximately15 cm), but more undulating surfaces may require >30 cm cutsfor precision grading.

In contrast to soil pH, decreased soil OM is a particularlynegative effect of land leveling. Since soil nutrient contentis related to soil OM content, natural nutrient availabilityand cycling is affected by decreased levels of soil OM (Rochette et al., 1999).The decline in soil OM will also adversely impactsoil structure (Caravaca et al., 2001; Watts et al., 2001; Franzluebbers, 2002),aggregate stability (Chenu et al., 2000; Caravaca et al., 2001),infiltration (Franzluebbers, 2002), and water-holdingcapacity (Haynes and Naidu, 1998; Diaz-Zorita et al., 1999),and increase the potential for soil erosion.

As indicated by the somewhat large positive and negative changesin the coefficients of variation for pre- and postleveling meanvalues (Table 1), land leveling affected the overall variabilityassociated with soil chemical properties. Results from Levene'stest for equal variances support this observation (Table 2).The variances associated with soil pH and S, Mn, and Cu contentssignificantly increased (P < 0.01) due to land leveling.

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Table 2. Effect of land leveling on the sample variance of soil chemical properties from the 0- to 10-cm depth. Asterisks next to post leveling values represent significant differences from Levene's tests in the sample variance of pre- and post leveling soil properties.

The increased variability among soil chemical properties couldcontribute to greater error in crop fertilizer recommendationsbased on routine soil analyses. A greater number of subsamplesper each composite sample would likely be needed to obtain accurateresults, especially when deep cuts are made and soil samplesare taken on a field-average, rather than site-specific, basis.Collecting soil samples based on land-leveling procedures orsite-specific technologies (i.e., cut and fill areas) is warrantedto help account for the greater in-field variability and a moreaccurate characterization of soil chemical properties. Sincea sample grid was used, significant changes in the variabilityof soil chemical properties indicates that land leveling musthave affected the spatial variability of soil chemical propertiesin terms of magnitude. However, the statistical analyses performedon these data cannot discern quantitative changes in spatialpatterns.

Preleveling range parameters from exponential and sphericalsemivariogram models for most soil chemical properties werelarge, >80 m, indicating spatial autocorrelation among samplingpoints at the 10-m spacing and that data were not truly independentwithin the sampling area (Table 3). Some degree of spatial independence(i.e., the range parameter <17 m) existed within the samplingarea for the contents of Mn and B. A spherical model best characterizedthe structure of the preleveling semivariograms for soil pH,EC, and the contents of K, Ca, Na, and Cu, but the model fitwas very poor for Ca and Cu (r² < 0.02). An exponential modelbest characterized the structure of the preleveling semivariogramsfor the contents of soil OM, P, S, Fe, Mn, Zn, and B, but themodel fit was also poor for P and Zn (r² < 0.36). A linearmodel best characterized the preleveling semivariogram for soilMg content. The spatial component [i.e., the C/(C₀ + C) columnin Table 3] explained between 50 and 99% of the variation inpreleveling soil chemical properties. However, land levelingaffected spatial relationships for a number of soil chemicalproperties.

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Table 3. Summary of geostatistical parameters for soil chemical properties measured before and after land-leveling. Results are reported for pre- and postleveling soil chemical properties based on the same model [i.e., spherical (S), exponential (E), or linear (L)].

The postleveling range parameter remained high for the majorityof soil chemical properties, while the spatial component generallyexplained a similarly large fraction of the total variabilityin postleveling as it did for preleveling soil chemical properties(Table 3). However, with the same model describing the structureof the preleveling semivariogram, the postleveling range parameterdecreased by more than 87% for the contents of soil OM, P, andZn indicating that some degree of spatial independence was gainedfor these soil chemical properties after land leveling, whereeach was spatially autocorrelated within the sampling area beforeleveling. Similar to the effect of land leveling on the spatialpatterns of soil OM, P, and Zn, land leveling caused Mn andB contents to be spatially autocorrelated within the samplingarea when some degree of spatial independence existed beforeleveling. In addition to geostatistical evidence for the effectsof land leveling on the spatial variability of soil chemicalproperties, changes in spatial distributions also illustratethe substantial effects of land leveling on soil chemical properties.

The spatial distributions of all soil chemical properties measuredin the top 10 cm were altered by land leveling. Portions ofthe sampling area with an alkaline preleveling soil pH had anacidic pH following land leveling as a result of exposing andmixing alkaline surface soil with the typically acidic subsoil(Fig. 1) . Similar spatial distribution changes occurred withsoil-extractable macro- (Fig. 2) and micronutrient contents(Fig. 3, 4) . The most noticeable changes occurred with thespatial distributions of soil OM (Fig. 1), K (Fig. 2), and S(Fig. 3) contents. Land leveling resulted in an average decreaseof 18% in soil OM in the top 10 cm. The decline in OM representsa substantial loss of potential native soil fertility for subsequentcrops. In contrast, land leveling caused the content of extractableK in the top 10 cm to increase by an average of 63%. As a cationsusceptible to leaching, K⁺ would have the tendency to leachfrom the surface and accumulate in the subsoil of flood-irrigatedsoils. Similarly, K is known to be associated with certain clayminerals like vermiculite and illite (Rich, 1968), which arefound in higher amounts in clayey subsoil, particularly in subsoilwith argillic horizons like the soil in this study. The exposureof K-rich subsoil by land leveling would potentially benefitthe K nutrition of subsequent crops grown in shallowly cut fields,such as rice and soybean (Norman et al., 2003). Although, Miller et al. (1990)indicated that K fertilization did not increaserice grain yields on some land-leveled soils in eastern Arkansas.

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Fig. 1. Pre- and postleveling spatial distributions of soil pH, electrical conductivity (EC), and organic matter (OM) content from the 0- to 10-cm depth. The x direction is North and the y direction is West on the land surface. The eastern roughly one-half of the area was cut and the western roughly one-half of the area was filled.

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Fig. 2. Pre- and postleveling spatial distributions of soil P, K, Ca, and Mg contents from the 0- to 10-cm depth. The x direction is North and the y direction is West on the land surface. The eastern roughly one-half of the area was cut and the western roughly one-half of the area was filled.

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Fig. 3. Pre- and postleveling spatial distributions of soil S, Na, Fe, and Mn contents from the 0- to 10-cm depth. The x direction is North and the y direction is West on the land surface. The eastern roughly one-half of the area was cut and the western roughly one-half of the area was filled.

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Fig. 4. Pre- and post-leveling spatial distributions of soil Cu, Zn, and B contents from the 0- to 10-cm depth. The x direction is North and the y direction is West on the land surface. The eastern roughly one-half of the area was cut and the western roughly one-half of the area was filled.

The significant increase in soil K content after leveling wassomewhat surprising since P, K, and other nutrients are typicallystratified in most agricultural soils in Arkansas due to surfacefertilizer placement, shallow tillage, and transport of subsoilnutrients to the soil surface by plants. The application ofnutrients in the poultry litter before collection of postlevelingsamples may have masked the true effects of land leveling onextractable soil nutrients. Potassium, as well as P, is generallystratified in the profile of these soils, where P and K tendto be highest in the topsoil and decrease with depth (Daniels et al., 2002).

One might expect that the areas that were initially cut andthe areas that were initially filled are observable in the mapsof the spatial distributions of soil chemical properties (Fig. 1– 4). However, it is difficult to associate changes insoil properties with cut and fill areas, except in cases ofextreme or deep-cut land leveling, because land-leveled areasare often graded several times after the initial cutting andfilling to smooth out topographic variations that resulted duringthe leveling process.

The effects of land leveling on soil chemical properties reportedhere are similar to those reported by Brye et al. (2003) forsoil physical properties and microbial biomass. It is evidentthat the agricultural practice of land leveling to improve thedistribution of irrigation water has several significant drawbacks,namely, the decline in potential long-term fertility with thedecrease in OM and the significant disruption of the spatialvariability and distributions of soil physical, chemical, andbiological properties.

Despite the numerous significant pre- to postleveling differencesobserved in this field study, collecting postleveling soil samplesapproximately 1 wk after application of poultry litter to thestudy site may have also introduced additional variability intothe postleveling results. The mode of litter application mayhave resulted in a nonuniform distribution of litter to thesoil surface within the study area. Despite removing surface-appliedlitter from the 20-cm radius around each grid point, relativelymoist soil conditions could have facilitated the leaching ofreadily solublized constituents contained in the litter intothe soil.

The application of poultry litter could have accounted for theentire increase in extractable soil P and could have contributedto increased extractable K (Table 1). However, litter applicationcould not have accounted for the increased magnitude of mostother extractable nutrients because the content of most othernutrients in poultry litter is not that high. The increasesin extractable Ca and Mg were likely due to exposure of subsoilfollowing land leveling with increased concentrations of Caand Mg due to a long history of using irrigation water highin these nutrients. In addition, if litter application had asignificant affect on postleveling soil properties, one wouldhave expected the soil pH and OM to have increased somewhat,but pH and OM actually decreased. In all likelihood, the poultrylitter masked more significant decreases in soil pH throughoutthe study area. Furthermore, the long history of irrigationin eastern Arkansas has resulted in ground water that has anelevated pH. Consequently, the ground water, which is the mostcommon source of irrigation water in eastern Arkansas, has contributedto the near-surface subsoil, which is the portion of the soilmanipulated in shallow-cut land leveling, having a similarlyhigh pH at least to the depth of the hardpan before acidic soilconditions are frequently encountered. Therefore, since relativelylittle time elapsed between litter application and postlevelingsample collection, we feel that the poultry litter applicationdid not compromise the results obtained to a significant degree.Furthermore, as discussed in detail in Brye et al. (2003), theaddition of poultry litter following land leveling likely resultedin an underestimation of the actual effect of land levelingon soil microbial biomass (Table 1).

Similar to the potential effects of the 1-wk between litterapplication and postleveling soil sampling, the 4-mo periodbetween pre- and postleveling soil sampling may have affectedsome variables, such as pH, EC, and several extractable soilnutrients, in ways that were unrelated to land leveling. However,periodic observations indicated the soil moisture status remaineduniformly wet between pre- and postleveling soil samplings,in which the prolonged wetness prevented use of heavy land-levelingequipment in the field until the soil dried out sufficiently,and the study area did not experience wetting and drying cycles.Furthermore, natural mineralization of OM would have been tooslow under the relatively cool and wet soil environment to havebeen responsible for the significant increases in numerous extractablesoil nutrients (Table 1). Therefore, we feel that any potentialtime effect between samplings on soil chemical properties wasinsignificant compared with the effects of the land levelingitself.

Relationships among Soil Chemical and Microbial Biomass
Numerous significant (P < 0.05) linear correlations existedamong soil chemical and microbial biomass before, after, andboth before and after land leveling (Table 4). Only the prelevelingrelationship between Zn and OM content resulted in a relativelystrong correlation (r = 0.76, P $≤$ 0.001). All other significantpreleveling correlations among soil chemical and microbial biomasshad correlation coefficients $≤$ 0.60. Following land leveling,the relationship between the Zn and OM content remained relativelystrong (r = 0.71, P $≤$ 0.001). In addition, postleveling Ca contentand pH had a relatively high positive correlation (r = 0.81,P $≤$ 0.001), while S content and pH had a relatively high negativecorrelation (r = –0.80, P $≤$ 0.001). Bacterial biomass contentdid not correlate with any soil chemical properties before orafter land leveling indicating that the bacterial populationthat exists in the top 10 cm of this silt-loam soil under aflood-irrigated, rice–soybean rotation is relatively insensitiveto the chemical status in the bulk soil of its surrounding environment.Microscale soil chemical properties most likely had a greaterinfluence on bacterial biomass. In contrast, the fungal biomassappeared to be much more sensitive to the chemical status ofits surrounding environment as fungal biomass content was significantly(P < 0.05), but generally not highly (–0.33 < r< 0.50) correlated with numerous soil chemical propertiesbefore and/or after land leveling. The numerous pre- and/orpostleveling correlations among soil chemical and microbialbiomass also suggests that land leveling may have resulted insignificant changes in the linear relationships among soil chemicaland microbial biomass.

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Table 4. Summary of pre- and postleveling Pearson linear correlations (r) among selected soil chemical properties and between soil chemical properties and bacterial and fungal biomass contents (g m^–2) and the fungal/bacterial biomass content ratio (F/B ratio).

Several linear relationships among soil chemical propertiesand microbial biomass changed significantly as a result of landleveling (Table 5). The slope and intercept parameters for therelationships between soil pH and extractable K, Mg, Na, andS contents; between EC and soil pH and extractable Ca, S, andMn contents; and between soil OM content and soil pH and extractableCa, Mg, S, and Mn contents were significantly affected by landleveling. In contrast, only the slope of the linear relationshipbetween soil OM and extractable Cu content (P = 0.021) and onlythe intercept for the linear relationships between EC and OMand extractable K and Na contents (P < 0.01) were significantlyaffected by land leveling.

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Table 5. Effect of land leveling on the relationships among selected soil chemical properties and between soil chemical and biological properties. A P $≤$ 0.05 for the slope and/or intercept parameter indicates land leveling caused the preleveling relationship to change significantly.

Similar to the effects on the relationships among soil chemicalproperties, land leveling also significantly affected linearrelationships between soil chemical and microbial biomass (Table 5).The slope and intercept parameters for the relationshipsbetween fungal biomass content and soil pH and extractable K,Ca, S, Mn, and Cu contents and between the fungal/bacterial-biomassratio and extractable Na and S contents were significantly affectedby land leveling. Only the slope of the linear relationshipsbetween fungal biomass content and extractable Mg and Na contents(P $≤$ 0.012) and between the fungal/bacterial-biomass ratio andextractable K and Cu contents (P $≤$ 0.05) were significantly affectedby land leveling. Only the intercept parameter for the linearrelationships between bacterial biomass content and EC and extractableK, Fe, Zn, and B contents were significantly (P < 0.04) affectedby land leveling. The slope and intercept parameters for thelinear relationships between the fungal/bacterial biomass ratioand extractable Na and S contents were significantly (P <0.02) affected by land leveling.

Management Implications
Variable growth and yield of rice and soybean on recently leveledfields in the mid-South are frequently attributed to the disruptionof soil fertility and plant nutritional status, which is typicallymanifested as plant nutrient deficiencies and/or toxicities.Preleveling soil-test results are ineffective at predictingpostleveling soil conditions and crop growth. The applicationof inorganic fertilizers often fails to improve or restore soilproductivity compared with the application of organic amendmentslike poultry litter, which, in the absence of plant-nutrition-relateddisorders, suggests a significant contribution from soil biologicalproperties in restoring productivity to leveled soils. Thoughthe addition of readily available plant nutrients and organicsubstrates from commercial fertilizers and organic amendmentsoffer a quick fix for the subsequent cropping cycle, restorationof chemical and biological equilibrium and proper soil functioningwill take time before newly exposed subsoil becomes acclimatedagain for high-yielding crop production. Numerous observationshave been made that suggest that the greater extent or depthof land leveling, the greater the grain yield decline, the longerthe time required for grain yields to be restored to acceptablelevels, and the more nutrient inputs required (Miller et al., 1990,1991; Norman et al., 2003).

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

The agricultural management practice of land leveling to facilitatemore uniform and economical distribution of irrigation waterto crops like rice and soybean is a severe form of soil disturbance.In this study, shallow land leveling activities significantlyaffected the magnitude, spatial variability, and spatial distributionsof soil chemical properties of a leveled Stuttgart silt loam.Land leveling was also responsible for significant alterationof linear relationships among many soil chemical and microbialbiomass.

Soil with sufficient moisture alone will not be highly productive.The benefit of improved water distribution must be weighed againstthe relatively severe and immediate alteration of soil propertiesand natural processes and the potential for future plant-growthproblems brought on by land leveling. Short- and long-term studiesthat evaluate the inter-relationships between soil physical,chemical, and biological properties will be essential for definingand/or refining management practices that expedite the restorationof productivity to precision-leveled soils.

ACKNOWLEDGMENTS

We gratefully thank Mr. Sam Counce and his family for allowingthis work to be conducted on their property. Jared Holzhauer,Jason Grantham, and Mandy Pirani are also acknowledged for theirfield assistance.

Received for publication April 29, 2004.

REFERENCES

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CONCLUSIONS
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