Soil Nitrate Concentrations Used to Predict Nitrogen Sufficiency in Relation to Yield in Perennial Grasslands

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Nitrogen Management

Soil Nitrate Concentrations Used to Predict Nitrogen Sufficiency in Relation to Yield in Perennial Grasslands

Sister Augusta Collins^* and Derek W. Allinson

Dep. of Plant Sci., Univ. of Connecticut, 1376 Storrs Rd., Storrs, CT 06269-4067

^* Corresponding author (rmaugusta{at}juno.com)

Received for publication March 3, 2003.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

A method of evaluating soil N present in a perennial grasslandsystem could help determine the need for additional N and enablemore accurate N fertilization recommendations. The purpose ofthis study was to establish a relationship between a criticallevel (CL) of soil nitrate N under perennial grassland and optimumyield in a three-harvest system. A range of fertilizer treatmentsfrom 0 to 613 kg ha^–1 was applied across two growing seasonsto mixed stands of perennial forage grasses at two sites inConnecticut. Soil samples were taken on a weekly basis, andsoil ammonium N and nitrate N were measured. Nitrate N was correlatedwith relative yield for three harvests within each growing season,and CLs of nitrate were generated using Cate–Nelson, linearresponse plateau, and quadratic response plateau models. Rangesof critical nitrate levels during the first 2 wk of each cyclewere established: 2.0 to 4.5 mg kg^–1 for the first harvest,4.0 to 9.8 mg kg^–1 for the second harvest, and 2.0 to11.0 mg kg^–1 for the third harvest. These values couldbe used to evaluate the necessity of adding N to a perennialgrassland system in a three-harvest rotation and aid in a morecorrect fertilization of perennial grasses by offering soil-specificN evaluations.

Abbreviations: CL, critical level • CN, Cate–Nelson (model) • LRP, linear response plateau (model) • PSNT, presidedress nitrogen test • QRP, quadratic response plateau (model) • RCBD, randomized complete block design • RCG, reed canarygrass • TF, tall fescue

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

INORGANIC SOIL N under perennial grassland can be measured,but such data are meaningless as a predictive tool unless correlatedwith plant response. Any measurement of soil N under activelygrowing grass indicates the amount present at that particulartime, not the N that will become available with mineralization.Soils under long-term grassland have large reserves of organicmatter accumulated from the constant recycling of dead and decayingmaterial (Whitehead, 1995). Organic N in the soil is mineralizedto ammonium that is quickly nitrified to nitrite and then to nitrate (Jansson and Persson, 1982; Schmidt, 1982). Previous speculationthat grasslands may inhibit nitrification (Theron, 1951; Soulides and Clark, 1958;Munro, 1966) has been disputed, and a recentreview of this topic has concluded that grasses do not releasecompounds inhibiting nitrification (Bremner and McCarty, 1993).Grasses take up N in both the NH₄⁺ and NO₃^– forms (Barraclough and Smith, 1987),but temperature, moisture, and pH conditionsunder perennial grassland typically favor nitrification, andNO₃^– is taken up as soon as it becomes available (Dorsey and Brown, 1935).As a result, NH₄⁺ concentrations are typicallyhigher than NO₃^– under perennial grasslands (Dorsey and Brown, 1935;Christensen, 1983; Davidson et al., 1990; Jarvis et al., 1990;Mallarino and Wedin, 1990).

Cool-season perennial grasses respond positively to N applications(Wedin, 1974; Allinson et al., 1992; Guillard et al., 1995;Whitehead, 1995). Quantities of N applied are largely determinedby the species' yield potential but may be in excess of 200kg N ha^–1 (Vetsch et al., 1999), and in temperate climates,the N applied is typically between 200 and 400 kg N ha^–1(Whitehead, 1995). Although a typical recommendation for perennialgrassland with less than 20% legume under high-level managementmay be 200 kg N ha^–1 (Jokela et al., 2004), yield responseshave been seen in orchardgrass (Dactylis glomerata L.) withapplications up to 400 kg N ha^–1 (Guillard et al., 1995)and in reed canarygrass (Phalaris arundinacae L.) with ratesbetween 280 and 336 kg N ha^–1 (Collins and Allinson, 1995;Vetsch et al., 1999). Knowledge of N cycling and availabilitywithin the soil could assist in avoiding excessive N application.

Various laboratory methods exist for estimating potentiallymineralizable N (Waring and Bremner, 1964; Stanford and Smith, 1972;Bundy and Meisinger, 1994; Cabrera et al., 1994). Laboratoryincubations are often slow, but sample turnover time must berapid if the producer is to effectively use the information.Field conditions are variable, and rates of N mineralizationdetermined in the laboratory do not necessarily translate tothe field (Wedin and Pastor, 1993). In situ field incubationshave been tried using buried soil bags (Eno, 1960; Westermann and Crothers, 1980)as well as exclusionary pipes combined withresin bags (Hart and Binkley, 1985), which have been criticizedas causing soil disturbance (Subler et al., 1995). The problemof soil disturbance affecting mineralization has been addressedby using two-dimensional anion exchange membranes when quantifyingNO₃^––N under perennial grassland (Collins and Allinson, 1999;Ziadi et al., 1999; Kopp and Guillard, 2002).

The potentially mineralizable N under a perennial grasslandafter plowing has been estimated cumulatively to reach 4000kg N ha^–1 over 20 yr (Whitmore et al., 1992) or as muchas 400 kg^–1 N ha^–1 yr^–1 in the first yearafter plowing (Clement and Back, 1969). Obviously, only a fractionof the potential N would become available through mineralizationwhen the grassland was not plowed. Nitrogen mineralization underunplowed perennial grassland may vary according to grass species(Wedin and Tilman, 1990), which has an effect on biomass allocation,root development, and rates of litter decomposition (Wedin and Pastor, 1993).A system for measuring and using the actual Navailable should reduce the application of excess N as wellas assure the application of sufficient N for optimum plantgrowth.

The problem of estimating potentially available soil N existsin many crops, especially in a humid climate where NO₃^––Ncould be rapidly lost from the system through leaching. A widelyadopted method used to evaluate N need with field corn (Zeamays L.) is the presidedress N test (PSNT) introduced in Vermontin 1984 (Magdoff et al., 1984). When a composite soil sampleis collected to a depth of 30 cm and plants are between 15 and30 cm tall, concentrations of soil NO₃^––N between21 and 25 mg kg^–1 consistently indicate sufficient N forcorn to attain optimum yield (Blackmer et al., 1989; Fox et al., 1989;Cerrato and Blackmer, 1991; Binford et al., 1992;Fox et al., 1992; Klausner et al., 1993). This test has provenmost reliable as an indicator of the CL of N beyond which addedN will not increase yield. The PSNT has been less successfulin determining what rates of N fertilizer to apply when soilNO₃^––N levels are less than the CL (Fox et al., 1989;Klausner et al., 1993). This test has also been used successfullywith sweet corn (Heckman et al., 1995) and fall-grown cabbage(Brassica oleracea L.) (Heckman et al., 2002) and was adaptedfor use with other vegetables such as lettuce (Lactuca sativaL.) and celery (Apium graveolens L.) (Hartz et al., 2000). Inall cases, it worked best in situations where N had been appliedas manure in substantial quantities over time and substantialmineralization could be expected.

One crop for which the PSNT has not been adapted is perennialgrassland grown for hay or pasture. The obstacles are obvious.As a perennial crop, the well-developed root system takes upNO₃^––N as soon as it becomes available. There isno readily accumulated reservoir of NO₃^––N to measureas there would be for an annual crop such as corn. Therefore,it was doubtful that a measure of soil NO₃^––N wouldhave any practical connection with the potential yield of thecrop. In addition, a cool-season grass hayfield is typicallyharvested three times during the growing season. Thus, the periodfor taking a soil sample and applying N if necessary must beearly in the growing season and immediately after each harvest.The purpose of our research was to evaluate the potential foradapting the PSNT to cool-season perennial grassland harvestedthree times during the growing season. Our goal was to determineif CLs of soil nitrate could be determined early enough in eachgrowth cycle to allow for the corrective application of fertilizerN. Soil samples collected on a weekly basis, over two growingseasons, in this system, were evaluated for their potentialto establish CLs of N for each growth cycle.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Field Procedures
Research was performed at two sites at the University of ConnecticutPlant and Soil Science Research Farm, located in Storrs, CT(41°48' N, 72°15' W). The first site had originallybeen seeded to reed canarygrass (RCG) and the second to tallfescue (Festuca arundinaceum Schreb.). At the time of the experiment,however, other species, including orchardgrass, sweet vernalgrass(Anthoxanthum odoratum L.), Kentucky bluegrass (Poa pratensisL.), and smooth bromegrass (Bromus inermis Leyss.) were present.Both sites had been in continuous sod for more than 16 yr andwere treated before experimental use with Crossbow (2,4-D [(2,4-dichlorophenoxy)aceticacid] and triclopyr {[(3,5,6-trichloro-2-pyrdinyl)oxy]aceticacid}), a broadleaf herbicide that was used to remove any straylegumes present in the plots, either as red clover (Trifoliumpratense L.) or white clover (Trifolium repens L.). The amountof legume initially present never exceeded 1 to 3%, so any Npossibly entering the system directly as a result of the legumekill would have been negligible. The herbicide was applied,however, to avoid any proliferation of red or white clover duringthe course of the research at the 0 or low-N treatments as hadbeen observed in an earlier project when low levels of N fertilizerhad been applied (Collins and Allinson, 1995). The soil wasa Paxton fine sandy loam (coarse-loamy, mixed, active, mesicOxyaquic Dystrudept).

Soils were analyzed initially and at the end of each growingseason. Phosphorus was applied on 6 May 1996 to supply 49 kgP ha^–1. Potassium was applied in split applications with93 kg K ha^–1 being applied on 6 May 1996 and 74 kg ha^–1being applied after the second harvest, on 21 July. The samerates of P and K were applied in 1997, with the first applicationon 22 April and the remainder of the K applied after the secondharvest on 29 July. All soils were extracted with a Modified-MorganNH₄(OAc) extractant, pH 4.8, 4 g 20 mL^–1 (McIntosh, 1969).Soil analysis data are presented in Table 1.

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Table 1. Soil fertility levels at each site through the sampling period.

A randomized complete block design (RCBD), with four replications,was used in 1996. The plots at the RCG site were each 13.6 by6.1 m while the tall fescue (TF) plots were 9.1 by 9.1 m. Theexperimental treatment was N rate (0, 175, 350, and 525 kg Nha^–1) applied as urea in 1996. In 1997, a split-plot designwas used. The main plots were the N treatments from 1996, andthe split plots were an additional 88 kg N ha^–1 addedto one-half of the original 1996 treatments. Hence, a totalof eight N rates (0, 88, 175, 263, 350, 438, 525, and 613 kgN ha^–1) were applied in 1997. The purpose in choosingsuch a wide range of treatments (0 to 613 kg N ha^–1) wasto ensure sufficient N available to reach a yield plateau. TheN was applied both years in split applications with one-halfof the total being applied as growth began in early spring,one-quarter applied after the first harvest, and one-quarterapplied after the second harvest. The dates of N applications,soil sampling, and harvests are listed in Table 2.

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Table 2. Dates for weekly soil sampling for 1996 and 1997 in relation to N application and harvest.

Harvest Yields
Three harvests were made in each year. The first harvests weretaken in June when the grass was flowering. Each plot was harvestedfrom the central 0.91-m area using a small-plot flail harvesterset to a cutting height of 6.4 cm. Fresh weights were takenin the field. Subsamples were taken and dried at 70°C toconstant weight to calculate kilograms of dry matter per hectare.

Weekly Soil Samples
Soil Sampling
Soil samples were taken on a weekly basis to a depth of 20 cm,from approximately 1 wk after each N application until harvest,both in 1996 and 1997. Three cores per plot were taken, bulked,and immediately set out to dry. The soil was sifted to passa 1.65-mm mesh and stored in airtight containers. Throughoutthe course of the experiment, the soil from all treatments wasanalyzed for organic matter using the weight loss-on-ignitionmethod (Ball, 1964). Soil samples were also analyzed for totalN and total C using a LECO Nitrogen/Protein Analyzer (ModelFP-2000, LECO, St. Joseph, MI).

Ammonium Nitrogen and Nitrate Nitrogen Determinations
Ammonium and NO₃^– were extracted using the procedure outlinedby Keeney and Nelson (1982). Extractants were analyzed colorimetricallyfor NO₃^––N and NH₄⁺–N on a Scientific Instrumentscontinuous flow analyzer (Westco, Danbury, CT), using a Cd columnfor reduction of NO₃^––N to NO₂^––N (USEPA, 1983)and an automated phenate method for NH₄⁺–N.

Statistical Analysis of Weekly Soil Sample Data
Both NO₃^– and NH₄⁺ data for each week were subjected toBartlett's test for homogeneity of variance, and log₁₀ transformationswere performed where necessary. In some cases the data remainednon-homogeneous after transformation, and a Friedman's non-parametrictest was performed in those instances. The data were analyzedas a RCBD in both years, since only the same N treatments forboth years were used in this analysis.

Mean NO₃^– and NH₄⁺ data for each N treatment from eachweek were plotted additively, that is the mean amount foundin the soil each week for each separate N treatment was addedto the amount for the previous weeks (Fig. 1 and 2). Thus, thevalue for any particular week can be determined by subtractingthe amount from the previous data point from that particularweek. The total additive values at the end of each season ateach site were analyzed as a RCBD in 1996 and as a split-plotdesign in 1997. In 1997, the soil samples taken during Week2, on 7 May, are not included in Fig. 2 because only the plotsreceiving the original four N treatments were sampled on thatday.

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Fig. 1. Additive soil NO₃^––N and NH₄⁺–N concentrations measured for successive weeks at four N rates at both sites during the 1996 season. Nitrogen applications are indicated with an inverted arrow. The ** and *** indicate significance at the 0.01 and 0.001 levels of probability, respectively. L, linear; Q, quadratic.

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Fig. 2. Additive soil NO₃^––N and NH₄⁺–N concentration measured for successive weeks at eight N rates at both sites during the 1997 season. Nitrogen applications are indicated with an inverted arrow. The *, ***, and NS indicate significance at the 0.05 and 0.001 levels of probability, and not significant, respectively.

The NO₃^– data for each week were plotted against relativeyield (%) to determine a CL in relation to optimum yield. Theterm relative yield is the yield expressed as a percentage ofthe plateau yield and is the chosen mode of expression to comparesites and years (Blackmer et al., 1989). Plateau yield was determinedby a series of reiterative single degree-of-freedom orthogonalcontrasts, which indicated the point at which no further yieldincrease in relation to N treatment occurred (Blackmer et al., 1989;Hooker and Morris, 1999). The relationship between NO₃^––Nextracted and relative yield was evaluated with the Cate–Nelson(CN), the linear response plateau (LRP), and the quadratic responseplateau (QRP) models, using the SAS Procedure NLIN (SAS Inst.,1999). A CL of NO₃^––N necessary to reach maximumyield was determined when the model was successful. The CL's,as well as each model's, capacity to describe the data, wereevaluated. The QRP and the LRP models were generated using theNLIN procedure in SAS (Goodnight and Ihnen, 1990), and the CN(Cate and Nelson, 1971) model was generated using the GLM procedurein the SAS statistical software (Goodnight et al., 1990).

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Harvest Yield
The two mixed stands of grasses used in this study, originallyseeded to RCG and TF, were both high yielding and generallyproduced yields that fell within the range of 8000 to 15000kg dry matter ha^–1. These yields are typical for intensivelymanaged grasslands in temperate regions (Whitehead, 1995). Themean dry matter total yield, over both years and all N ratesfor the RCG site, was 11118 kg ha^–1, with a maximum of14303 kg ha^–1 at 525 kg N ha^–1 in 1996 and 14244kg ha^–1 at 613 kg N ha^–1 in 1997. Tall fescue produceda mean dry matter yield of 9811 kg ha^–1 over both years,with a maximum of 12508 kg ha^–1 at 350 kg N ha^–1in 1996 and 11149 kg ha^–1 at 263 kg N ha^–1 in 1997.These compared well to maximum yields of RCG reported by Vetsch et al. (1999)of 11760 and 11558 kg ha^–1 at N rates of280 and 336 kg ha^–1 in two consecutive growing seasonsand 13104 kg ha^–1 at 672 kg N ha^–1 reported by Smith (1981).It was greater than the maximum yield of TF reportedby Collins and Allinson (1995) of 9117 kg ha^–1 at 280kg N ha^–1 and Buckner and Cowan (1973), who reported 7000to >9000 kg ha^–1 as typical of well-fertilized TF plotsand indicated that a plateau yield had been reached at bothsites from which a corresponding CL of soil NO₃^––Nwas deduced.

A significant linear response to N occurred at both sites foreach harvest each year (Table 3). In many cases, there was asignificant quadratic response as well, especially at the TFsite where yield peaked at 350 kg N ha^–1 in 1996 and at263 kg N ha^–1 in 1997. At the RCG site, significant quadraticresponses were also noted. With the exception of Harvest 3 in1997, the highest yields came in response to the highest N level.The same trends were true for the total yield at both siteseach year.

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Table 3. Yields for each harvest and total yields at both sites according to N rates for 1996 and 1997.

The mean organic matter content of the soil was 81 g kg^–1at the RCG site and 77 g kg^–1 at the TF site, which iswithin the realm of 50 to 100 g kg^–1 characterized byWhitehead (1995) as typical of perennial grassland that hasbeen in sod for several years. There was no significant differencein organic matter in relation to N treatment at either site(data not shown), but there was a significant linear responseover time at both sites (Table 4). The mean total N across allN treatments was 3.0 g kg^–1 at the RCG site and 2.8 gkg^–1 at the TF site (Collins, 2000). A concomitant long-termlaboratory incubation study using these soils (Collins and Allinson, 2002)based on the method of Stanford and Smith (1972) had estimatedthat 323 kg N ha^–1 yr^–1 could possibly be mineralizedfrom soil at the RCG site and 325 kg N ha^–1 yr^–1from the TF site, if the ideal laboratory conditions had existedin the field. This falls within the range of 200 kg N ha^–1yr^–1 estimated by Whitmore et al. (1992) and 400 kg Nha^–1 estimated by Clement and Back (1969) in the firstyear after plowing.

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Table 4. Organic matter compared over time.

Inorganic Nitrogen in Weekly Soil Samples
The 1996 data indicated that N applied at 175 kg ha^–1did not result in excess NO₃^– in the soil (Fig. 1). However,after the second N application on Day 170 (18 June), at bothsites, soil NO₃^––N levels were noticeably greater(when added together over time) when application amounts greaterthan 175 kg N ha^–1 were applied. In 1997, when eight levelsof N were used, a similar trend for increased soil NO₃^–levels could be observed after the third application on Day210 (29 July) at both sites when rates in excess of 263 kg Nha^–1 were used (Fig. 2). This indicated that up to 263kg N ha^–1 was being readily taken up by the forage andwas positively affecting yield. These results agree with thework of Vetsch et al. (1999), who found that RCG yield was optimalat N rates ranging from 224 to 336 kg N ha^–1, dependinglargely upon precipitation. Although the sum of NH₄⁺ concentrationswas affected by N rate, NH₄⁺–N was present constantlyin the soil, even at the 0 N treatments where the sum of allweeks was greater than 400 kg ha^–1 at each site at theend of the growing season. This was in contrast to NO₃^––Nconcentrations that were consistently low for the 0, 88, and175 kg N ha^–1 treatments. This agrees with the findingsof Dorsey and Brown (1935) and Mallarino and Wedin (1990), whofound consistently high concentrations of NH₄⁺–N throughoutthe growing season under perennial grassland, regardless ofN treatment.

Concentrations of NO₃^––N and NH₄⁺–N extractedon a weekly basis were significantly affected by N rate (Table 5).This was particularly so for NO₃^––N concentrations.Generally, the response was linear, but occasional quadraticand cubic responses were noted as well. While weekly NH₄⁺–Nconcentrations were sometimes significantly different (Table 5),the differences were evident primarily during the firstgrowth period, and the inconsistent response would make it lessuseful as a tool for determining CLs needed for N application.

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Table 5. Significance of nitrate and ammonium extracted from soil samples by week from the two sites for 1996 and 1997, in relation to N treatment.

Critical Nitrate Nitrogen Levels
Using the three models—CN, LRP, and QRP—severalweeks were found in each growth period when a significant relationshipoccurred between soil NO₃^––N and yield. In the three-harvestsequence, N fertilizer was applied in early spring, and thebeginning of the first growth period was designated as 6 wkbefore the first harvest. Thereafter, N was applied immediatelyafter the first and second cutting, and the growth period lasted6 wk until the next harvest. Because it is best to apply N fertilizerearly in the growth cycle or immediately after a harvest tomaximally affect successive yields, the first 2 wk of each growthperiod were judged to be the most important time period forapplication of N. The percentage error for Quadrants I and II(CN model), R², and CLs (all models), from the pooled data ofthe first 2 wk of each growth period for 1996 and 1997 at thetwo sites, is presented in Fig. 3.

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Fig. 3. Pooled data for years and sites, showing Weeks 1 and 2, using three models to determine percentage error (Cate–Nelson only), R² values, and critical nitrate levels (CL). The *** indicates significance at the 0.001 level of probability.

In general, the relationship between soil NO₃^––Nand relative yield for the first week of Growth Period I couldnot be described by the models (data not shown). Only in Week1 of 1996 at the TF site did the CN model describe the data,and a CL of 2.1 to 2.2 mg NO₃^––N kg^–1 wasdetermined. For each of the other growth periods, both the first-and second-week data were described by the models and were highlycorrelated (P < 0.001) with relative yield.

The capacity of each model to describe the data was similar,based on the R² values. However, the CN model (Cate and Nelson, 1971)that partitions the data into four quadrants also describesthe error rate. It is based on the percentage of points in theupper left quadrant (I), which would overpredict the need forN and the lower right quadrant (II), which would underpredictthe need for N (Fox et al., 1989). A relative yield of 0.88was used as the horizontal CL, as this best partitioned thedata into the upper right and lower left quadrants, which isthe goal of the CN model. In general, the points in the upperleft quadrant indicate that even though a plateau yield hadbeen reached, N would have been recommended because the NO₃^––NCL had not been reached. Similarly, points in the lower rightquadrant indicate that the CL was reached, but the plots didnot reach plateau yield. Thus, no fertilizer N would have beenrecommended, and reduced yields would have been obtained. Inthe first case, excess nutrient loading may have entered intothe environmental system, and in the second, lack of N applicationwould have resulted in reduced yields. The CLs produced usingthe CN model showed combined error rates of 16, 22, 14, 14,and 12% and therefore 84, 78, 86, and 88% accuracy rates. Thesevalues compare well to the 31% error rate reported in relationto the PSNT for corn by Sims et al. (1995), the 18.1, 22.2,and 23.8% error rates reported by Fox et al. (1992) for theMid-Atlantic states, and the 16% error rate reported by Klausner et al. (1993)in New York. For the most part, the CLs reportedfor the PSNT were determined in fields that had been consistentlyfertilized with manure. Sims et al. (1995) reported that thegreater portion of their error (24%) occurred in the upper leftquadrant, thus indicating a low CL that was not responsive toN. This could result if the available N was below the rootingzone of the crop or if for some other reason, the N presentin the soil had only been released after the soil sample hadbeen taken. Similarly for our data, the percentage error wasgreater in the upper left quadrant for the first two growthperiods, but not for the third, and would err on the side ofrecommending that N be added when plateau yield would have alreadybeen achieved.

The range of CLs was usually greater for the second week thanfor the first. The QRP model generally had the highest CLs,whereas the CN model tended to recommend the lowest. These threemodels followed a similar trend to that reported by Hooker and Morris (1999),who determined a range of CLs for the late-seasoncornstalk nitrate test. That is, the CN reported the lowestvalues, the LRP a midrange value, and the QRP the highest CLvalues. A summary of the range of CLs described by the threemodels for the three growth periods encompassing both yearsis presented for Weeks 1 and 2 in Table 6. Rather than selectone value based on one model, it seems more prudent to use therange suggested by the three models taken together.

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Table 6. Range of critical soil NO^–₃ levels for each of three growth periods in Weeks 1 and 2 of a 6-wk growth cycle for optimum yield, representing data from 1996 and 1997, at two sites.

The CN model was successful in generating low percentage errorrates, and the LRP and QRP models were successful in generatingsignificant R² values. The CLs generated by all three modelscould, therefore, be used to analyze the weekly NO₃^––Ndata indicating the amounts of NO₃^– necessary at eachgrowth period to reach a plateau yield. Basically, the CLs suggesteda range of 2.0 to 4.5 mg kg^–1 for Weeks 1 and 2 of GrowthPeriod 1, 3.8 to 10.0 mg kg^–1 for Growth Period 2, and2.0 to 11.0 mg kg^–1, for Growth Period 3 (Table 6). Althoughthese numbers are less than the 25 mg kg^–1 CL necessaryfor corn to reach optimum yield, a simultaneous study usingburied bags, based on the technique of Eno (1960), to quantifyactual NO₃^––N nitrified in these plots during eachgrowth period had indicated a mean CL of 25 mg kg^–1 underthese same grasslands when removal of NO₃^– through uptakeor leaching was eliminated (Collins, 2000). Because the literaturedoes not indicate grassland CLs to which these data can be compared,the fact that the mean CL was the same when NO₃^––Nwas not removed as the PSNT suggests that the grassland wouldactually follow the same pattern as the corn data. It offerspromise that the CLs that were determined reflect an accurateNO₃^––N concentration using these models to assurethat a plateau yield would be reached in relation to the threegrass harvests. A similar experiment using anion exchange membraneswithin the same perennial grassland sites had generated a comparablerange of CL values in units of µg cm^–2 d^–1.The membranes had been left in the soil for up to 12 d thatextended over time rather than being subjected to the point-in-timelimitations of individual soil samples (Collins and Allinson, 1999).Both the soil samples and membrane strips indicated thata CL could be derived in perennial grassland when sufficientamounts of fertilizer had been added to reach plateau yield.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Critical NO₃^––N levels were generated in relationto optimum yield for the first 2 wk of three harvest cyclesin each of two seasons, 1996 and 1997. The range of CLs generatedcould be used to indicate the soil NO₃^– concentrationnecessary for a field to reach optimum yield. If that valuewere reached, no further N should be needed. However if it werenot reached, there would be sufficient time for N applicationwhen necessary to reach optimum yield and eliminate a potentialN deficiency. The CN model generally recommended the lowestCLs whereas the QRP model recommended the highest. Using thisdata to analyze soil samples for NO₃^––N at the criticaltime in relation to each harvest could offer more specific informationin relation to soil mineralization potential than is currentlyavailable through cropping history, manure application, andyield potential.

ACKNOWLEDGMENTS

The authors gratefully acknowledge the help of Dr. Tom Morrisand Dr. Karl Guillard with the statistical analyses used inthis research and for early review of the manuscript.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Allinson, D.W., K. Guillard, M.M. Rafey, J.H. Grabber, and W.M. Dest. 1992. Response of reed canarygrass to nitrogen and potassium fertilization. J. Prod. Agric. 5:595–601.

Ball, D.F. 1964. Loss-on-ignition as an estimate of organic matter and organic carbon in non-calcareous soils. J. Soil Sci. 15:84–92.

Barraclough, D., and M.J. Smith. 1987. The estimation of mineralization, immobilization and nitrification in nitrogen-15 field experiments using computer simulation. J. Soil Sci. 38:519–530.

Binford, G.D., A.M. Blackmer, and M.E. Cerrato. 1992. Relationships between corn yields and soil nitrate in late spring. Agron. J. 84:53–59.

Blackmer, A.M., D. Pottker, M.E. Cerrato, and J. Webb. 1989. Correlations between soil nitrate concentrations in late spring and corn yields in Iowa. J. Prod. Agric. 2:103–109.

Bremner, J.M., and G.W. McCarty. 1993. Inhibition of nitrification in soil by allelochemicals derived from plants and plant residues. p. 181–218. In J.-M. Bollag and G. Stotzky (ed.) Soil biochemistry. Vol. 8. Marcel Dekker, New York.

Buckner, R.C., and J.R. Cowan. 1973. The fescues. p. 297–306. Forages. 3d ed. Iowa State Univ. Press, Ames.

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