Need for a Soil-Based Approach in Managing Nitrogen Fertilizers for Profitable Corn Production

doi:10.2136/sssaj2005.0034

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Nutrient Management & Soil & Plant Analysis

Need for a Soil-Based Approach in Managing Nitrogen Fertilizers for Profitable Corn Production

R. L. Mulvaney^*, S. A. Khan and T. R. Ellsworth

Dep. of Natural Resources and Environ. Sci., Univ. of Illinois, 1102 S. Goodwin Ave., Urbana, IL 61801

^* Corresponding author (mulvaney{at}uiuc.edu).

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Nitrogen fertilization for corn (Zea mays L.) production hasrelied extensively on yield-based recommendations that weredeveloped to represent regional averages, yet are routinelyapplied to individual fields, on the assumption that fertilizerN serves as the major supply for crop N uptake. Using data from102 on-farm N-response studies, an evaluation was conductedof the Illinois proven-yield (PY) method for accuracy and economicprofitability on a site-by-site basis. As additional objectives,the Illinois soil N test (ISNT) was evaluated for detectingwhether N fertilization was economical, and for quantifyingcrop response to N fertilization relative to soil and managementfactors. For 18% of the site-years studied, N recommendationsby the PY method were accurate to within 20 kg ha^–1, whereas13% were underfertilized by 25 to 129 kg ha^–1 (60 kg ha^–1on average) at a current cost of $5 to $170 ha^–1 ($75ha^–1 on average), and 69% were overfertilized by 21 to235 kg ha^–1 (103 kg ha^–1 on average) at a cost of$12 to $130 ha^–1 ($57 ha^–1 on average). The lattergroup included 30 site-years that were completely nonresponsiveto N fertilization, all but two of which were predicted by site-averageISNT values assuming a critical test level of 230 mg kg^–1.This level was exceeded for 19 of 69 responsive site-years,mostly during 2001–2003 when corn followed soybean (Glycinemax L. Merr.) with high plant populations. A higher criticaltest level would have been required under such conditions, owingto more extensive residue inputs that would promote microbialN immobilization, and increased crop uptake of mineralized soilN. The ISNT was significantly related to crop N requirement,and was the most powerful predictor of error in PY recommendations(P < 0.001).

Abbreviations: ANOVA, analysis of variance • EONR, economically optimum N rate • EOY, economically optimum yield • FNUE, fertilizer N uptake efficiency • ISNT, Illinois soil N test • PY, proven-yield • SD, standard deviation

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

SINCE THE 1970s, N fertilizer recommendations for midwesterncorn production have relied on a yield-based system, wherebyan expected yield goal is multiplied by a constant factor (typically19.4–24.2 kg N Mg^–1 or 1.1–1.4 pound N bushel^–1),with adjustments to account for N credits from previous croppingor the recent use of manure (e.g., Illinois Agronomy Handbook, 2002).This system utilizes a mass balance approach that assumesconstant efficiency in crop uptake of fertilizer and soil N(Stanford, 1973; Meisinger, 1984; Meisinger et al., 1992). Yield-basedsystems were originally intended as a first approximation inmaking generalized fertilizer N recommendations for long-termperiods on a regional scale, but have been applied indiscriminatelyto fertilize individual fields in a particular growing season.

Implicit to yield-based N recommendations is the presumptionthat mineralization is a negligible source for crop N uptake,which would necessarily imply that yield in the absence of appliedN supplies a fixed proportion of crop N uptake that is substantiallyless than that from fertilizer. Yet unfertilized (check) plotyields in N-response studies often exceed the yield increaseobtained with fertilization (Lory and Scharf, 2003), and inmany of these studies, sites have been detected where corn iscompletely nonresponsive to fertilizer N (e.g., Bundy and Malone, 1988;Blackmer et al., 1989; Fox et al., 1989; Schmitt and Randall, 1994).Such sites have often been excluded in averaging responsedata to evaluate yield-based N recommendations (e.g., Vanotti and Bundy, 1994;Brown, 1996; Lory and Scharf, 2003; Nafziger et al., 2003),but even so, the recommended rates tend to beexcessive. This was the case, for example, with 96% of 193 responsivesite-years analyzed by Lory and Scharf (2003), for which therecommended N rate exceeded the economically optimum N rate(EONR) by up to 227 kg ha^–1 (90 kg ha^–1 on average).More importantly, recommended and optimum N rates were not correlatedsignificantly (r = 0.04) in the latter study, suggesting thatyield-based N recommendations lack predictive value. The sameconcern has been raised previously by researchers in Iowa (Peterson and Corak, 1993;Blackmer et al., 1997), Wisconsin (Vanotti and Bundy, 1994;Bundy, 2000), Pennsylvania (Fox and Piekielek, 1995),and Ontario (Kachanoski et al., 1996).

The only hope for improving fertilizer N recommendations forcorn production in a humid region such as Illinois is to accountfor a soil's capacity to supply plant-available N through mineralization.The usual approach has been to measure soil NO₃^–, eitherbefore or after planting. Some success has thereby been achievedin detecting nonresponsive sites (e.g., Bundy and Malone, 1988;Blackmer et al., 1989; Schmitt and Randall, 1994), althoughcomplications arise from the need for special sampling protocoland from spatial and temporal variability in soil NO₃^–concentrations, which depend on numerous N-cycle processes,including mineralization, immobilization, nitrification, denitrification,leaching, and plant uptake.

A better approach would focus on the soil's N-supplying capacityby estimating mineralizable organic N, which is subject to fewerN-cycle processes than NO₃^– and should thus be less dynamic.Research since the 1950s has provided growing support for theconcept that soil organic matter is not uniformly mineralizable,but consists primarily of a passive fraction accompanied bya less extensive pool of biologically active organic N associatedwith microbial biomass (e.g., Jansson, 1958; Paul and Juma, 1981;Mengel, 1996). The latter constituents are identifiedlargely as ${alpha}$ -amino N and (amide + amino sugar)-N, both of whichhave been linked to net mineralization and/or crop N uptakein pot experiments (Mengel, 1996).

Several attempts were made during the 1960s and 1970s to providea chemical basis for soil management effects on crop growthand fertilizer N response under field conditions; however, theresults generally indicated little variation in the distributionof N, and the usual conclusion was that no particular fractionof hydrolyzable soil N is more labile than others (e.g., Keeney and Bremner, 1964;Khan, 1971; Meints and Peterson, 1977). Thisconclusion has been widely accepted, but must be questionedin light of recent evidence that conventional steam-distillationmethods do not permit quantitative analyses for amino sugarN or amino acid N (Mulvaney and Khan, 2001). Based on the latterfinding, simple diffusion methods were developed for N-distributionanalysis of soil hydrolysates that are accurate, specific, andreliable.

In subsequent work by Mulvaney et al. (2001), the newly developeddiffusion methods were applied to soil samples collected byBrown (1996), from sites that differed in whether corn had beenresponsive to N fertilization. The results showed a much higherconcentration of amino sugar N for nonresponsive than for responsivesoils, whereas no consistent difference was detected in theirconcentrations of total hydrolyzable N, hydrolyzable NH₄⁺–N,or amino acid N. Upon incubation, mineral N production was foundto be much more extensive by nonresponsive than by responsivesoils, and to be accompanied by a net decrease in amino sugarN but not in amino acid N (Mulvaney et al., 2001). Based onthese findings, a simple soil test, the so-called Illinois soilN test (ISNT), was developed that estimates amino sugar N withoutthe need for hydrolysis (Khan et al., 2001). When this testwas applied to 25 site-average soil samples collected by Brown (1996)to a depth of 30 cm, a critical range of 225 to 240 mgkg^–1 completely resolved 12 nonresponsive from 13 responsivesoils.

The present study originated with the objective of evaluatingthe effectiveness of the ISNT in differentiating responsivefrom nonresponsive site-years under a wide range of soil andcropping conditions. As additional objectives, the databasethereby generated was used to assess (i) how these conditionsmight influence a quantitative relationship between ISNT valuesand crop responsiveness to N fertilization; and (ii) the accuracyand economic consequences of N recommendations by the PY method,primarily on a site-by-site basis. Very little peer-reviewedinformation is available on the latter issue, despite the factthat this method has been promoted for several decades in manystates through university extension publications.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Field Plot Management
The work reported herein involved 102 N-response experimentslocated throughout Illinois, largely on farmer fields. Of theseexperiments, 51 were reported by Brown (1996), including 11conducted in 1990, 18 in 1991, and 22 in 1992.An additional51 experiments included 14 in 2001, 16 in 2002, and 21 in 2003.In each case, N rates were applied according to a randomizedcomplete block design with four replicates, by sidedressingurea-NH₄NO₃ solution (360 g N L^–1) when corn was 15 to30 cm tall. In 1990, 1991, and 1992, plots measured approximately4 m in width x 15 m in length, and N applications were basedon a PY recommendation, assuming soil productivity under highmanagement (Fehrenbacher et al., 1978). Nitrogen was appliedat 0, 20, 40, 60, 80, or 100% of the recommended rates in 1990,and at 0, 25, 50, 75, 100, or 125% of these rates in 1991 and1992. In 2001, 2002, and 2003, plots measured approximately5 m in width x 15 m in length, and N applications ranged from0 to 235 kg ha^–1, in equal increments of 33.6 kg ha^–1.At each site, an adapted corn hybrid was planted in rows spaced76 cm apart in April or May. Thinning was done before N applicationat V3 to V6, so as to obtain a uniform population within theexperimental area. At physiological maturity, grain yield wasdetermined by hand-harvesting 9 m of the two middle rows, andwas adjusted to a constant moisture content (155 g kg^–1).

Soil Samples
Soil samples were collected from the experimental area at eachsite in late March or early April, including surface (0–18cm) samples for routine soil fertility assessment (pH, P, andK) and profile samples for NO₃^– testing (1990–1992)or the ISNT (2001–2003). Surface samples were collectedas a 5-core composite from the entire experimental area, usinga 2.5-cm diam. probe. The cores were dried at room temperature(1990–1992) or in a forced-air oven at 40°C (2001–2003),crushed with a mechanical grinder to pass a 2-mm screen, andthen mixed thoroughly before analyses for pH, available P, andexchangeable K as described by Mulvaney et al. (2001), and fororganic C and total N as described by Khan et al. (2000). Thedata are summarized by Table 1, according to soil series forsite-years identified as responsive or nonresponsive to N fertilization.

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Table 1. Characterization of soils for site-years studied in N-response experiments.

Profile samples were collected to depths of 0 to 30 and 30 to60 cm in 1990–1992, and from 0 to 15, 15 to 30, and 30to 60 cm in 2001–2003. In each case, five soil cores werecollected from each block using a 5-cm (for 0- to 30-cm samples)and then a 2.5-cm (for 30- to 60-cm samples) diam. probe, combinedby depth, and subsequently frozen (–10°C) within 12h after collection. Before use, core samples collected in 1990–1992were allowed to thaw at room temperature, screened while stillfield-moist to <2 mm, and then air-dried at room temperature,with subsequent transfer for storage in polyethylene or paperbags. In 2001–2003, profile samples were dried in a forced-airoven at 40°C, and were then crushed in a hammer mill to<2 mm.

Analytical Methodology
The N test described by Khan et al. (2001) was performed asspecified in a technical note (¹⁵N Analysis Service, 2004) concerningthe ISNT, which describes three modifications to improve theuniformity of heating with the griddle employed (Model 76220;West Bend, West Bend, WI): (1) replacement of the original temperaturecontroller with an electronic unit, (2) enclosure of the griddlewithin a polyethylene box as a draft shield, and (3) rotationof jar positions after heating for 1.5 and 3 h. To ensure thevalidity of ISNT data, care was taken that heating was alwaysdone at the same measured temperature (54°C), samples wereanalyzed in triplicate (for 2001–2003 samples) or quadruplicate(for 1990–1992 samples), and a reference soil sample wasincluded on each griddle.

For 1990–1992 site-years, analyses by the ISNT were performedon a composite sample of air-dried soil (0–30 cm) preparedby combining an equal weight of soil collected from each block.For 2001–2003 site-years, block samples were analyzedindividually, and ISNT data for 0 to 30 cm were generated byaveraging values measured for 0 to 15 and 15 to 30 cm. Analyseswere also performed on the 30- to 60-cm samples collected forthe latter group, but are reported for only a single site-yearto demonstrate an interaction with crop N response.

Experimental Site-Years
The 102 site-years studied are characterized by Tables 2 and3, which show the soil series; the year when N response wasstudied; the previous crop; the tillage system in use; the sourceand amount of manure N applied for the growing season studied,as well as residual manuring within the previous 2 to 5 yr;plant population estimated from stand counts; a site-averageISNT value and the standard deviation (SD) computed from four(1990–1992) or 12 (2001–2003) replicate values;check-plot corn yield data; and the magnitude of the error inthe PY recommendation and the corresponding economic cost. Foreach site-year, a recommended N rate was determined as describedin the Illinois Agronomy Handbook (2002), using productivityindices reported by Fehrenbacher et al. (1978) for high management(1990–1992 site-years) or by Olson and Lang (2000) foroptimum management (2001–2003 site-years). In the caseof nonresponsive site-years (Table 2), the magnitude of errorin the PY recommendation was obtained as the recommended N rate,and the economic cost was calculated on the assumption thatfertilizer N costs $0.55 kg^–1.

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Table 2. Characterization of nonresponsive site-years.

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Table 3. Characterization of responsive site-years.

Site-years were identified as nonresponsive (Table 2) or responsive(Table 3) for N fertilization of corn, based on regression analysesperformed by fitting a linear, linear plateau, quadratic, orquadratic plateau model to N-rate and mean yield data usingMicrosoft Excel 2003 software (Microsoft Corp., Redmond, WA)configured with Solver as an add-in. A response model was selectedfor each site-year on the basis of residual analysis and theChi-Square test for goodness of fit. In the case of responsivesite-years, economically optimum yield (EOY) and EONR were computedby the resulting regression equation assuming a value of 0.1for the N/corn price ratio; delta yield (Kachanoski et al., 1996)was obtained as the difference between the EOY and check-plotyield [which in some cases was achieved with a fall applicationof 7–78 kg N ha^–1 as (NH₄)₂HPO₄]; fertilizer N uptakeefficiency (FNUE) was estimated as delta yield/EONR; and errorin the PY recommendation was calculated from the difference,recommended N– EONR. To estimate an economic cost foroverfertilized site-years, the latter difference was multipliedby $0.55 kg^–1 N, whereas with an insufficient N recommendation,a cost was computed assuming $98.42 Mg^–1 for yield lossestimated by regression and a credit of $0.55 kg^–1 forunused N.

Analysis of Variance
After excluding 18 site-years involving an obvious limitationto crop growth or fertilizer N response (site-years 2, 10, 11,17, 21, 34, 41, 43, 50, 52, 54, 57, 77, 91, 92, 99, 101, and102), plus two others where corn followed wheat (site-years35 and 43), the Proc MIXED procedure within SAS (SAS Institute, 1998)was employed to examine the effects of both categorical[year (treated as a random effect); previous crop; tillage;manuring (current and residual or residual only)] and continuous(population and ISNT value) variables on soil organic C, sidedressedN, EOY, delta yield, EONR, FNUE, and PY error (kg ha^–1)as dependent variables. Tukey-Kramer tests were performed incarrying out pairwise comparisons of treatment means.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Evaluation of Yield-based Nitrogen Management
The importance of fertilizer N management in corn productionis clearly evident from the economic costs that often exceed$100 per hectare. The rationale for this investment residesin the PY method, whereby crop N uptake is ascribed largelyto N fertilization. The resulting recommendations have beenwidely adopted on the premise that yield must not be limitedby inadequate N supply, yet have seldom been evaluated relativeto grain yield with a lower (or higher) rate of N fertilization,or for accuracy in fertilizing individual sites where N-responsestudies have been conducted to determine an EONR. Such studiesprovide the basis for the evaluations reported in Tables 2 and3, which indicate the magnitude of the error in the PY recommendationfor each site-year studied and the corresponding economic cost.Table 4 summarizes the latter information for site-years underdifferent crop rotations or with current manuring.

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Table 4. Effectiveness of the proven-yield (PY) method for site-years under different management.

Tables 2 and 3 provide good reason to question the validityof the PY method, as check-plot yields ranged from 1.9 to 13.1Mg ha^–1 (8.2 Mg ha^–1 on average, representing 77%of the average EOY) for the 52 site-years that received no inputof N from sidedressing, manuring, or fall-applied (NH₄)₂HPO₄.The implicit capacity of the soil to provide plant-availableN, as reflected in these values, cannot be adequately accountedfor in making PY recommendations, which assumes that the soilsupplies a constant proportion of crop N uptake.

Considering all 102 of the N-response trials reported herein,PY recommendations were accurate to within 20 kg ha^–1for only 18 of the site-years studied, while 69% of these recommendationswere excessive, involving the majority of both nonresponsiveand responsive site-years. Underfertilization occurred with13% of the latter group, and accounted for the most seriouseconomic loss observed. There were four cases where N utilizationwas limited by a prolonged moisture stress; the usual and expectedresult was overfertilization.

In 22 of the N-response experiments reported, manure had beenapplied for the growing season studied, so the PY recommendationwas adjusted to incorporate standardized credits for manureN (Illinois Agronomy Handbook, 2002). The adjustment provedinadequate, except for identifying three nonresponsive site-yearswhere the manure credit exceeded the N requirement estimatedfor the yield goal. Of the 19 remaining currently manured site-years,15 were completely nonresponsive to N fertilization, but wouldhave received 38–159 kg N ha^–1 by the PY methodat a cost of $21 to $88 ha^–1. Fertilization also wouldhave been recommended for the four additional site-years wherea yield response was observed. Three of the latter cases involveda corn–soybean rotation, and the combined N credits wouldhave led to underfertilization. In contrast, the PY method wouldhave overfertilized a responsive site-year under continuouscorn, for which the manure credit was inadequate. The implicationis that a credit approach cannot provide a reliable basis forquantifying manure N availability, as has been reported previously(Hansen et al., 2004). This would indeed be expected given theinherent complications associated with such factors as manureC and N concentrations, N losses through NH₃ volatilization,and inaccuracies in manure application.

A further problem arises because the PY method does not accountfor residual availability of manure N, which can persist forseveral years after application (Eghball and Power, 1999; Eghball et al., 2004).The resulting impact on soil N availability wasverified in the present project by using Fisher's Exact Testto evaluate the effect of manure history on crop N responsefor site-years under continuous corn or in a corn–soybeanrotation without current manuring. A significant differenceat P < 0.01 was thereby found, in which 82% of the nonresponsivesite-years in this group had a history of manuring, as comparedwith 16% of those that were responsive. Residual manure wasa more common occurrence when corn was grown continuously thanin rotation with soybean. The latter difference is particularlyapparent for nonresponsive site-years that were not currentlymanured, among which were all seven of those under continuouscorn but only two of four that were in a corn–soybeanrotation. The PY recommendations were always excessive for continuouscorn (by 49–235 kg N ha^–1, at a cost of $27–$130ha^–1), with or without a response to N fertilization,whereas either under- or overfertilization occurred when therewas a manure history for corn in rotation with soybean.

As with current manuring, fixed N credits are utilized in PYrecommendations when corn is grown after a legume. The presentproject involved 54 such site-years that had not been manuredfor at least 1 yr before the growing season studied, including49 in a corn–soybean rotation and five where first-yearcorn followed alfalfa. Of the latter group, four site-yearswere nonresponsive to N fertilization, but would have been fertilizedwith 105 to 123 kg N ha^–1 by the PY method at a cost of$58 to $68 ha^–1, even after maximizing the alfalfa credit(112 kg N ha^–1). The error was more extensive in magnitude(162–193 kg N ha^–1) and cost ($89–$106 ha^–1)for four nonresponsive site-years where corn followed soybean,involving either no-till (site-years 6 and 22) or residual manuring(site-years 15 and 33). In contrast, underfertilization oftenoccurred when a yield response was obtained with soybean asthe previous crop, whereas no such occurrences were observedwith continuous corn, suggesting a greater need for N fertilizationwhen corn follows soybean. The latter difference was substantiated,after excluding manure and tillage effects, by an ANOVA thatshowed significant (P < 0.0001) increases in EONR and deltayield when the previous crop was soybean rather than corn. TheEONR estimated for corn after soybean was significantly (P <0.0001) greater for 2001–2003 (153 kg N ha^–1) thanfor 1990–1992 (96 kg N ha^–1) site-years, suggestingthat current production practices have increased the fertilizerN requirement of corn within this rotation. Such an increaseis likely attributable to greater nutrient demand by improvedhybrids selected for maximal yields with high planting rates.

These findings raise serious questions about the use of standardizedcredits for estimating the fertilizer value of legume-derivedN, which ranges widely with species and environmental conditions(Heichel and Barnes, 1984). An inherent difficulty arises, forexample, because plant uptake of mineral N reduces symbioticfixation (e.g., Giöbel, 1926; Thornton, 1946), and thusa single legume credit cannot suffice for soils that differconsiderably in their capacity for mineralization (Kurtz et al., 1984).In the case of soybean, a positive credit may oftenbe inappropriate, because the grain has a higher N concentrationthan with corn, and soil N removal can be much more extensive(Gentry et al., 1998). In the present project, a soybean creditwas inappropriate for nonmanured site-years under a corn–soybeanrotation, as one-third of this group would have been underfertilizedby the PY method, at an average cost of $57 ha^–1.

Lacking any N credit for management history, PY recommendationswere excessive for all but one of the 23 site-years under continuouscorn that had not received manure for the growing season studied(although in almost 50% of these cases, manure had been appliedwithin the previous 2–5 yr). Almost one-third of thisgroup was nonresponsive to N fertilization, as compared with<10% of the 49 site-years in a corn–soybean rotationwith no manure credit. While on average both groups were overfertilizedby the PY method, the error was much more extensive (128 versus46 kg N ha^–1 as calculated using actual errors ratherthan the magnitudes reported in Table 4) when corn was the previouscrop (P < 0.01), with no instances of underfertilization.These findings may be explained in part by a more extensiveoccurrence of residual manure and a larger input of fertilizerN applied annually to continuous corn, which promotes residuedecomposition with microbial production of labile soil N thatwould reduce fertilizer N response (Shen et al., 1989; Stevens et al., 2005).

Based on Tables 2 to 4, the preceding discussion raises seriousquestions about the practical value of the PY method for fertilizingindividual sites, as does the fact that EOY (data not shown,but readily calculable as yield without sidedressed N plus deltayield) was not related to EONR (r = 0.08). This method likewiseproved to be inaccurate when fertilizer N recommendations wereaveraged for the 102 site-years studied, contrary to the usualjustification for yield-based N management. A value of 154 kgN ha^–1 was thereby obtained, as compared with 90 kg Nha^–1 for the average EONR. The difference was reducedbut not eliminated by excluding the 33 nonresponsive site-years,in which case the PY recommendation averaged 38 kg N ha^–1higher than did the EONR (131 kg ha^–1). The latter strategyhas often been employed in reporting N-response trials but cannotbe justified, as the PY method provides no a priori basis foridentifying nonresponsive site-years.

Evaluation of Soil-based Nitrogen Management
The recurring evidence of serious inaccuracy in fertilizer Nrecommendations by the PY method has obvious economic implicationsfor individual farmers, and also raises concern about environmentalpollution. Extrapolating from the average error in these recommendationsfor the site-years studied ($50 ha^–1), the annual costto Illinois agriculture would exceed $220 million, which doesnot include additional expenses associated with excessive Nfertilization, such as the loss of Ca²⁺, Mg²⁺, and K⁺ that serveas counterions during the leaching of NO₃^–. Such estimatesemphasize the need to account for a soil's capacity to supplyplant-available N through mineralization, which is the key toimproving fertilizer N management in a humid region such asIllinois. The ISNT was developed precisely for this purpose,and is designed to estimate an alkali-1abile fraction of soilN, nominally referred to as amino sugar N, which has been relatedto net N mineralization (Mulvaney et al., 2001). The same relationshiphas been observed in several previous investigations to evaluatevarious alkaline reagents as a chemical index of soil N availability(e.g., Cornfield, 1960; Gianello and Bremner, 1988; Vanotti et al., 1995;Mengel, 1996), whereas soil organic matter measurementsare of limited value for the latter purpose (e.g., Schmidt et al., 2002;Walley et al., 2002).

As originated, the ISNT is employed to identify sites whereN fertilization is ineffective for increasing corn yield, althoughan obvious potential also exists for estimation of fertilizerN requirements, in lieu of yield-based N management. Assumingthe same critical test value determined by Khan et al. (2001)for 25 site-years in 1990 to 1992 (230 mg kg^–1) as a firstapproximation in evaluating soil N availability without consideringmanagement history, the ISNT was 94% effective in identifyingsite-years characterized in the present project by the lackof an economic yield response to N fertilization. The majorityof this group had been manured for the growing season studied,or had received manure within the previous 2 to 5 yr while croppedto continuous corn. As shown by Table 5, all but two such site-yearswere detected successfully by the ISNT, the only exceptionsoccurring when yield data were erratic within and among replicateplots, which tended to show a similar pattern of variabilityin soil test values. Moreover, the ISNT was completely effectivein predicting 8 site-years that were nonresponsive to fertilizerN following previous cropping to soybean or alfalfa.

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Table 5. Effectiveness of the Illinois soil N test (ISNT) for differentiating responsive from nonresponsive site-years for N fertilization of corn.

The present project also involved 69 site-years that were responsiveto N fertilization. Of these, 50 were correctly identified onthe basis of the same critical test value noted previously,while the remaining 19 would have been identified as nonresponsivebecause this value was exceeded. The latter group raises anapparent concern about the utility of the ISNT for fertilizerN management, but also provides an opportunity to gain valuableinsight about interactions that affect crop N requirement, andthereby affect the critical level for interpreting test values.Both topics are addressed by the following discussion, althoughnecessarily through scientific inference concerning factorsknown to affect crop growth and nutrient requirements, sincethe work reported was not designed to quantify specificallysuch effects.

In order for the ISNT to be utilized successfully, conditionsmust be conducive to soil N mineralization, as well as cropN uptake and utilization. This requirement was not satisfiedwith four of the 19 site-years incorrectly identified as nonresponsiveby the ISNT, owing to serious moisture stress that occurredfor most (site-years 101 and 102) or some (site-years 76 and79) of the growing season. The effect of this stress on interpretationof the ISNT is clearly demonstrated from a comparison of yielddata for site-years 22 and 76, which involved the same locationwith ISNT values above the critical level, but different growingconditions. Rainfall was adequate to promote mineralizationthroughout the 2001 growing season, whereas a 6-wk period occurredwithout appreciable rainfall during May and June of 2003, whichdrastically decreased check-plot yield and led to a dramaticyield response to N fertilization.

Interpretations of ISNT data can also be vitiated if fertilizerN requirement is increased by other factors that reduce soilN availability or crop N utilization, such as weed competitionor a soil fertility limitation. This was the case with one responsivesite-year (no. 95) where weed competition would have decreasedcrop uptake of soil and fertilizer N, and with six others forwhich the critical test value was exceeded with a pH of 5.0to 5.2 (site-years 57 and 92), Bray-1 P at 14 to 21 mg kg^–1(site-years 34, 54, and 57), or exchangeable K at 103 to 132mg kg^–1 (site-years 55 and 59). Soil acidity would haveimpeded mineralization, thereby reducing the availability oflabile soil N estimated by the ISNT, whereas a deficiency ofP or K would have decreased the physiological efficiency ofplant N utilization for grain production. This decrease wasclearly reflected in a high EONR (Table 3) that was larger whenthe limitation involved K instead of P. The latter differencemay be related to mineralization, which served as a supplementalsource of P but not K.

Although often overlooked in fertilizer recommendations promotedduring the past three decades, and generally neglected in thescientific literature on soil fertility, plant population hasbeen recognized as a crucial factor in the successful use ofsoil testing (Bray, 1948; Melsted and Peck, 1973). A fundamentalinteraction thereby arises, such that a certain critical soiltest level could become inadequate if the planting rate wereincreased. This is exactly what has been observed with the ISNT.In the original work by Khan et al. (2001), a test level of225 to 235 mg kg^–1 was completely effective in identifying12 of 25 site-years as nonresponsive to N fertilization, basedon N-response trials conducted between 1990 and 1992 with 47400 to 68 900 (60 700 on average) plants ha^–1. When thesame critical ISNT range was applied in the present project,eight failures occurred that are of particular interest becausethe test value exceeded the critical range, yet a crop N responsewas obtained with no apparent limitation in growing conditions.Two of these failures involved continuous corn in 1991 or 1992with a plant population of 60 300 or 64 600 (62 400 on average)plants ha^–1 (site-years 85 and 90), but delta yield wasquite limited (0.6 Mg ha^–1 on average) with a marginaleconomic return ($9 ha^–1 on average). The failure rateincreased substantially in 2001–2003 with six site-yearsin a corn–soybean rotation that were planted to a higherdensity of 66 000 to 77 500 (70 800 on average) plants ha^–1(site-years 56, 61, 66, 87, 88, and 98), in which case a six-foldincrease also occurred in delta yield (average of 3.7 Mg ha^–1).Table 3 provides many examples of greater N response with higherplant populations, for site-years having similar ISNT values,as further evidenced by an ANOVA that showed a significant (P< 0.05) increase in EONR with population for responsive site-years.These findings would be expected if fertilizer N requirementis subject to a fundamental interaction between soil N availabilityand plant demand, as is readily apparent from studies by Lang et al. (1956).A higher planting rate would thereby increasethe critical level for interpreting the ISNT.

The interaction of the ISNT with plant population is clearlydemonstrated by Table 6, which summarizes the magnitude of cropN response for site-years broadly grouped into two populationclasses representing only 1990–1992 (<61 000 plantsha^–1) or largely 2001–2003 (>61 000 plants ha^–1)site-years, and three ISNT classes consisting of site-yearsidentified as highly responsive (<190 mg kg^–1), moderatelyresponsive (190–229 mg kg^–1), or nonresponsive ( $≥$ 230mg kg^–1) to N fertilization. The data in Table 6 leavelittle doubt about the need for soil-based N management, asfertilizer N requirement decreased with increase in the ISNT,while an increase occurred with plant population, reflectinghigher crop N demand. The latter trend adds a new dimensionto fertilizer N management with the ISNT, whereby planting ratecan be adjusted to fully exploit soil N availability, providedthat productivity is not limited by other soil properties (e.g.,moisture). Moreover, Table 6 suggests that the ISNT may providevaluable input for optimizing planting rate, although economicfactors must also be considered.

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Table 6. Interaction of the Illinois soil N test (ISNT) and plant population in affecting crop N response.

Soil testing is inherently more complicated for N than for Por K, due in part to the fact that mineralization and immobilizationare highly dependent on the quantity and quality of C availablefor microbial utilization. This interaction would necessarilyaffect the predictive value of the ISNT for estimating soilN availability following a recent incorporation of carbonaceousresidues, such as bedding-laden manure or a nonleguminous covercrop. The latter explanation applies to one of the ISNT failuresobserved (site-year 66), in which case rye (Secale cereale L.)had been grown as an overwinter catch crop following soybeanand would have promoted immobilization after being incorporatedby spring tillage.

The same effect of C is implicated for five other site-yearsunder a corn–soybean rotation, which were characterizedby a high soil content of organic C (21–27 mg kg^–1)when incorrectly identified as nonresponsive by the ISNT in2001–2003 (site-years 56, 61, 87, 88, and 98). The testvalues thereby obtained suggest a considerable capacity formineralization that would have promoted uptake of soil N bythe previous soybean crop, thereby reducing the role of symbioticfixation in meeting the high N requirement of this legume. Theresulting decrease in soil N availability, combined with theabsence of annual N fertilization, would have impeded decompositionof corn stover, potentially contributing to microbial competitionfor available N, and hence promoting a crop N response, duringthe growing season studied. This possibility would be enhancedby the growing trend toward high planting rates for corn andsoybean, and is consistent with previous work by Studdert and Echeverría (2000)showing a longer half-life for soilorganic C with a corn–soybean rotation, as compared withcontinuous corn. When these two rotations were compared by anANOVA that removed tillage and manure effects, a significantdifference was obtained at P < 0.05, involving a greaterorganic C content for site-years where corn followed soybean(22.7 g kg^–1), as opposed to corn (17.8 g kg^–1).The implication is a higher critical level for the ISNT whencorn is grown in rotation with soybean.

As has generally been observed, ISNT values decreased with depthof sampling, for each of the 2001–2003 site-years listedin Tables 2 and 3. The magnitude of this decrease was especiallymarked for site-years 87 and 88, both of which were locatedwithin a field where corn had repeatedly been grown in the pastfor silage production. The low test values thereby obtainedfor the 30- to 60-cm depth (data not reported) suggest a limitationin subsoil fertility, which may have contributed to fertilizerN responsiveness that would not have been predicted by testingthe surface 30 cm. Any such limitation would have been exacerbatedfor these site-years because of their high plant populationsthat would have increased competition for uptake of water andnutrients. The result would have been deeper and more extensiverooting, as observed in several field studies by Pavylochenko (1937).

Utilizing the traditional approach for yield-response trials,the work reported involved replicate field plots in a balancedstatistical design, so as to define a site-average relationshipbetween ISNT values and crop N response. The availability ofwithin-site data for 2001–2003 studies revealed that yieldswere often erratic in comparing different N rates within a block,as well as among blocks. In such cases, ISNT values for differentblocks tended to reflect a similar pattern of spatial variation.This association is clearly evident from Table 7, for a site-yearidentified as nonresponsive from averaged data when one blockwas actually responsive. The latter response coincided withthe lowest ISNT values, particularly for the 30- to 60-cm depth,and test values were generally consistent with block differencesin check-plot yield. There is an obvious implication that theeffectiveness of the ISNT will depend on sampling scale, whichshould be adequate to characterize the area sampled for yieldmeasurement. Equally obvious is a potential for site-specificN management.

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Table 7. Spatial variability among replicate blocks for site-year 17 in Illinois soil N test (ISNT) values and crop N response.

If the ISNT measures a mineralizable form of soil N, then apositive relationship should exist between test values and grainyield without incremental N fertilization (i.e., check-plotyield). This relationship was confirmed by carrying out an ANOVA,and was found to be highly significant (P < 0.001). The samelevel of significance was observed in differentiating responsivefrom nonresponsive site-years by the ISNT and in relating testvalues to delta yield, EONR, and FNUE. The latter effects werenegative, as would be expected because crop N response and fertilizerrequirement would be reduced by more extensive mineralization.The mineral N thereby generated is ignored in making yield-basedfertilizer N recommendations, and as noted previously for thePY method, the result is often overfertilization. The potentialvalue of the ISNT for fertilizer N management was clearly demonstratedby an ANOVA to compare different parameters in accounting forthe errors we observed in PY recommendations. Significant effectswere observed for only two of the parameters evaluated. Besidesthe previous crop (P < 0.05), the ISNT was the most powerfulpredictor (P < 0.001).

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

A yield-based approach for fertilizer N management is inherentlyflawed by the underlying assumption that soil N provides a constantproportion of crop N uptake, and by the use of fixed creditsto estimate the input of N from recent manuring or a previouslegume. The usual result is overfertilization, although as demonstratedherein, the PY method can lead to underfertilization with acorn–soybean rotation. The economic and environmentalconsequences can be alleviated in a humid region by adoptinga soil-based approach that quantifies the effect of mineralizationon plant N availability.

The ISNT far surpassed the PY method in identifying sites whereN fertilization was completely ineffective, and also provedto be sensitive to quantitative differences in soil N availability,suggesting that yield-based N rates can be reduced when testvalues are high. In order for this test to be utilized successfully,soil sampling must be done on an appropriate scale and to adepth consistent with ISNT calibration, and interpretationsmust account for crop rotation, planting density, and any occurrenceof a soil fertility limitation.

ACKNOWLEDGMENTS

We thank L. C. Gonzini and J. J. Warren for conducting the field-plotresearch reported, T. J. Smith for assistance with data collectionand soil series identifications, Dr. S. Aref for the statisticalanalyses presented, Dr. C. S. Mulvaney for prayerful supportand suggestions, and the farmers whose cooperation providedthe site-years studied. Partial support for this research wasobtained from the Fertilizer Research and Education Council.

Received for publication January 26, 2005.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
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