Foliar Nitrogen Application Timing Influence on Grain Yield and Protein Concentration of Hard Red Winter and Spring Wheat

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

PRODUCTION PAPER

Foliar Nitrogen Application Timing Influence on Grain Yield and Protein Concentration of Hard Red Winter and Spring Wheat

Anthony G. Bly^* and Howard J. Woodard

Plant Sci. Dep., South Dakota State Univ., Box 2207A, Brookings, SD 57007

^* Corresponding author (anthony_bly{at}sdstate.edu)

Received for publication December 13, 2001.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
CONCLUSIONS
REFERENCES

Foliar N applications on wheat (Triticum aestivum L.) have increasedgrain protein. Foliar N timing evaluations have been minimal.The objectives were (i) determine the optimal timing of foliarN for increased grain protein of hard red winter wheat (HRWW)and spring wheat (HRSW), (ii) evaluate effect of foliar N ongrain yield, and (iii) determine relationship of grain proteinto foliar N application and grain yield. Foliar N was appliedat Feekes stage 10.0 (boot) or 10.8 (postpollination) on twocultivars of HRWW and HRSW each year from 1995 to 2000. Thefoliar N rate (33.7 kg N ha^-1) was applied as 1:1 solution ofurea ammonium nitrate (UAN) and water. Fertilizer N for a 3360kg ha^-1 grain yield goal was broadcast as UAN after planting.Soil type was Estelline silt loam (fine-silty over sandy orsandy-skeletal, mixed, superactive, frigid Calcic Hapludoll).Postpollination foliar N gave the highest grain protein duringall years. Grain yield was significantly reduced 5% by bootstage foliar N for HRSW. Neither timing application significantlyreduced HRWW grain yield. All wheat data were pooled to relategrain yield level and protein response to foliar N. Grain proteinand yield from plots without foliar N were inversely related(r² = 0.57). Postpollination foliar N increased protein 70%of the time when yield goal was exceeded compared with only23% when it was not. These results show that postpollinationfoliar N gave higher grain protein and was most effective whenplanned yield goal was exceeded.

Abbreviations: HRSW, hard red spring wheat • HRWW, hard red winter wheat • UAN, urea ammonium nitrate

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
CONCLUSIONS
REFERENCES

WHEAT GROWERS CAN ADD VALUE to hard red wheat by increasinggrain protein concentration. Price deductions that are incurredfrom selling wheat grain with protein concentration that islower than market standard can be greater than premiums paidfor grain protein concentration higher than the standard. Pricedeductions and premiums vary by year. Standard market grainprotein concentrations for hard red wheat in the Upper Midwestof the USA have been 12 and 14% for HRWW and HRSW, respectively.

Nitrogen is the major nutrient that influences wheat grain yieldand protein concentration. When the amount of available soilN limits yield potential, additions of N fertilizers can substantiallyincrease grain yield. However, grain protein concentration candecrease if the amount of added N is not adequate for potentialyield (McNeal and Davis, 1954; Terman et al., 1969; Olson et al., 1976;Grant et al., 1985). Many researchers have foundthat late-season topdress N additions as dry fertilizer materialswere the most effective in attaining higher grain protein concentration(Fowler and Brydon, 1989; Vaughan et al., 1990; Stark and Tindall, 1992;Wuest and Cassman, 1992; Knowles et al., 1994). Otherresearchers have measured increases in grain protein concentrationfrom applications of late-season N either as foliar sprays ordry topdress fertilizers even though early-season N applicationswere more than sufficient for potential grain yield (Pushman and Bingham, 1976;Westcott, 1998).

Research reports investigating the influence of foliar-appliedN on wheat grain protein concentration are not common. A foliarN application applied as a liquid spray resulted in higher grainprotein concentration levels than when N was broadcast as drygranular fertilizer at later growth stages on wheat not grownafter fallow (Alkier et al., 1972; Strong, 1982). Evaluatingrates of foliar N on ‘Butte-86’ HRSW in North Dakota,Endres and Schatz (1993) found that grain protein concentrationincreased as foliar N rate was increased. However, the 33.7kg N ha^-1 rate provided the greatest incremental increase ingrain protein concentration. Finney et al. (1957) evaluatedthe application timing of foliar N on ‘Pawnee’ HRWWin Kansas. They found that grain protein concentration increasedover the control treatment with each foliar N rate incrementand was maximized with an application timing after anthesis(Feekes 10.5) (Simmons et al., 1995).

Wheat growers need to know when grain protein concentrationwill most likely be increased by foliar N application on moderncultivars. Therefore, the objectives of this research were todetermine the optimal timing of foliar N application on HRWWand HRSW for increased grain protein concentration, the effectof foliar N on grain yield, and the relationship of grain proteinconcentration to foliar N application and grain yield.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
CONCLUSIONS
REFERENCES

Separate field experiments for HRWW and HRSW were conductedin each of 6 yr from 1995 to 2000 on the Crop Improvement ResearchFarm near the campus of South Dakota State University in Brookings.The soil type was Estelline silt loam (fine-silty over sandyor sandy-skeletal, mixed, superactive, frigid Calcic Hapludoll).For all site years, the previous crop was soybean [Glycine max(L.) Merr.] to which no fertilizer nutrients were applied. Twocultivars of HRWW (Rose and Redland) and HRSW (Butte-86 andSharp) were used throughout the study. No-till management practiceswere used each year. Seeds were planted in rows with 17.8-cmspacing at 3 million pure live seeds ha^-1. Preplant compositesoil samples were obtained from each study location for determiningrequired nutrient recommendations for N, P, K, and Cl for a3360 kg ha^-1 yield goal (Gerwing and Gelderman, 2001). The recommendedrate of N was applied immediately after planting as broadcastUAN and ranged between 56 and 150 kg ha^-1 (Table 1). Pests anddiseases were controlled chemically.

View this table:
[in this window]
[in a new window]

Table 1. Soil test N and fertilizer N rate applied to hard red winter and spring wheat foliar N timing projects at Brookings, SD, for 1995 to 2000.

The foliar N timing treatments were applied at boot and postpollinationgrowth stages. A check treatment without foliar N applicationwas also included in each replication. The foliar N (33.7 kgN ha^-1) solution was a 1:1 mixture of UAN and H₂O. Conditionswere predisposed toward worst-case scenario leaf burn by applyingthe foliar N on days when precipitation was not expected within24 h and when daily air temperature was highest. The foliarN solution was applied to treatment plots with a spray hoodto prevent contamination of adjacent plots.

Plot size was 1.5 by 10.7 m, and all treatments were randomizedin complete blocks and replicated four times. Grain was harvestedwith a plot combine (SPC-20, Almaco, Nevada, IA), and yieldswere calculated from the weight of the grain from each plot.Grain protein concentration was determined with near-infraredspectroscopy (1995–1997: Technicon InfraAnalyzer 300,Bran + Luebbe, New York; 1998–2000: INFRATEC 1229 GrainAnalyzer, Foss Tecator AB, Hoganas, Sweden). Grain moisturewas adjusted to 13% for yield and protein concentration calculations.Dependent-variable statistics were determined with SAS (SASInst., 1996). Regression and figures were completed with Excel97 (Microsoft Corp., 1997).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
CONCLUSIONS
REFERENCES

Grain Yield
Foliar N timing, year, and year x cultivar sources of variationsignificantly influenced HRSW grain yields (Table 2). The significantinfluences of the year and year x cultivar sources of variationon grain yield were expected due to differences in growing seasonconditions from year to year. Grain yield of HRWW was significantlyinfluenced by year, cultivar, and the year x cultivar interaction(Table 3). As with HRSW, these sources of variation were expectedto be significant.

View this table:
[in this window]
[in a new window]

Table 2. Analysis of variance for effects of year, cultivar, and foliar N timing on hard red spring wheat grain yield and protein concentration at Brookings, SD, during years 1995 to 2000.

View this table:
[in this window]
[in a new window]

Table 3. Analysis of variance for effects of year, cultivar, and foliar N timing on hard red winter wheat grain yield and protein concentration at Brookings, SD, during years 1995 to 2000.

Across all years for HRSW, the yield from plots in which foliarN was applied at the boot stage was significantly lower comparedwith the check treatment (2701 vs. 2856 kg ha^-1, respectively)(Table 4). However, with the postpollination foliar N application,HRSW mean grain yield was significantly reduced in only 1 (1997)of the 6 yr (Table 4). Leaf burn occurred after all foliar Napplications. Leaf burn measurements were not taken, but itis speculated that leaf burn was the probable cause for theslight grain yield reductions that were found with the foliarN treatments.

View this table:
[in this window]
[in a new window]

Table 4. Hard red spring wheat grain yield and protein concentration means as influenced by foliar N timing at Brookings, SD, for 1995 to 2000.

Foliar N timing did not influence HRWW grain yield (Table 5).Mean HRWW grain yields were very similar, indicating that theadded N from the foliar N application did not have an influenceon grain dry matter accumulation. Leaf burn was also observedbut appeared to be less than for the HRSW. Air temperatureswere generally cooler when foliar N was applied to the HRWWcompared with the foliar N timings for the HRSW. This probablyresulted in less leaf burn and therefore less influence on grainyield in HRWW.

View this table:
[in this window]
[in a new window]

Table 5. Hard red winter wheat grain yield and protein concentration means as influenced by foliar N timing at Brookings, SD, for 1995 to 2000.

Grain Protein Concentration
Foliar N timing significantly influenced grain protein concentrationfor both HRWW and HRSW (Tables 2 and 3). Year and cultivar hada significant influence on grain protein concentration and canbe explained by the year-to-year variation in growing conditionsand genetic variation between cultivars. The cultivar x timinginteraction was nonsignificant for both HRWW and HRSW, indicatingthat these cultivars respond similarly to the same foliar Napplication.

Grain protein concentration was greatest when foliar N was appliedat the postpollination growth stage for HRSW and HRWW (14.7and 12.6%, respectively) (Tables 4 and 5). Foliar N appliedat the boot growth stage also significantly increased mean grainprotein concentration compared with the check (14.4 vs. 14.2%for HRSW and 12.2 vs. 11.8% for HRWW) but produced less of anincrease than foliar N applied at postpollination (Tables 4and 5). This agreed with research by Finney et al. (1957), whoobserved that foliar N applied after flowering resulted in highestgrain protein concentration levels. Analysis by year indicatedthat foliar N applied at the postpollination growth stage resultedin the significantly highest grain protein concentration during2 of the 6 yr for HRSW and 3 of the 6 yr for HRWW (Tables 4and 5).

Grain Protein Concentration and Yield Relationship
Grain protein concentration increases from foliar N applicationoccurred quite frequently even though adequate N (soil and fertilizer)was provided for the planned yield goal. Nine of the 12 siteyears in this study had significant grain protein concentrationresponses to foliar N application. An increase in grain proteinconcentration could prevent price deductions and possibly couldresult in premiums returned to the producer in favorable years.The ability to predict a possible grain protein concentrationincrease from a foliar N application would be helpful for wheatproducers. The decision to apply foliar N should be made duringthe growing season. Information is required to assist wheatproducers in deciding if grain protein concentration will beenhanced. Estimation of potential grain yield during the growingseason and/or plant N analysis as an indicator of plant N sufficiencycould be these sources of information.

Potential grain yield predictions could be used because N isa major component of dry matter production and accumulationin the grain. If grain yield is predicted to exceed the plannedyield goal, N available for grain protein concentration partitioningcould be less than required for desirable grain protein levels.In this study, grain yield and protein concentrations of thecheck plots were inversely related. This trend is consistentwith other research (Partridge and Shaykewich, 1972; Pushman and Bingham, 1976;Grant et al., 1985; Peltonen, 1992). Therelationship between grain yield and protein concentration wasgood (Fig. 1) . This regression equation was determined fromthe check plots only, for the purpose of evaluating the influencethat grain yield level had on grain protein concentration withoutany influence from foliar N application. The HRSW had higherprotein concentration and lower yields while the HRWW had highergrain yield had lower protein. A majority of the plot yieldsexceeded the planned yield goal of 3360 kg ha^-1 (Fig. 1). Theplanned yield goal for the HRWW was probably too low.

View larger version (29K):
[in this window]
[in a new window]

Fig. 1. Grain yield and protein relationship of hard red winter wheat (HRWW) and hard red spring wheat (HRSW) plots without foliar N application from studies during 1995–2000 at Brookings, SD.

Foliar N application increased grain protein concentration on70% (III/(III + IV) x 100) of the plots that exceeded the plannedyield goal. However, only 23% (I/(I + II) x 100) of plots withyields lower than the planned yield goal had increased grainprotein concentration (Fig. 2) . The relationship between relativegrain yield and protein concentration was derived from the postpollinationfoliar N treatment because it gave the greatest increase ingrain protein concentration. Despite the separation of the HRWWand HRSW plots in Fig. 2, the need of foliar N to increase grainprotein concentration is required in grain yield environmentsthat exceed the planned yield goal.

View larger version (20K):
[in this window]
[in a new window]

Fig. 2. Relative grain yield and protein concentration of hard red spring wheat (HRSW) and hard red winter wheat (HRWW) plots with foliar N applied postpollination from studies during 1995–2000 at Brookings, SD.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS CONCLUSIONS REFERENCES

The data from this research would suggest that foliar N be appliedto growing wheat at the postpollination growth stage if thefollowing requirements are met:

Grain yield is predicted to exceedplanned yield goal.
Grain protein premiums from increasingprotein or deductionsfrom low protein are expected to be greaterthan the economicinvestment in the foliar N application.

ACKNOWLEDGMENTS

This research was partially funded by the South Dakota WheatCommission and the South Dakota Agricultural Experiment Station.The authors thank Dwayne Winther (Senior Agricultural Technician)for his dedicated assistance to this project and his designand construction of the spray hood used to apply the foliarN treatments and also Dr. Ron Gelderman for his advice and interesttoward this research.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
CONCLUSIONS
REFERENCES

Alkier, A.C., G.J. Racz, and R.J. Soper. 1972. Effects of foliar- and soil-applied nitrogen and soil nitrate-nitrogen level on the protein content of Neepawa wheat. Can. J. Soil Sci. 52:301–309.

Endres, G., and B. Schatz. 1993. Foliar N applied post-anthesis to enhance wheat grain protein. Misc. Publ. North Dakota State Univ., Carrington Res. Ext. Cent., Carrington, ND.

Finney, K.F., J.W. Meyer, F.W. Smith, and H.C. Fryer. 1957. Effect of foliar spraying of Pawnee wheat with urea solutions on yield, protein content, and protein quality. Agron. J. 49:341–347.[Abstract/Free Full Text]

Fowler, D.B., and J. Brydon. 1989. No-till winter wheat production on the Canadian prairies: Timing of nitrogen fertilizers. Agron. J. 81:817–825.[Abstract/Free Full Text]

Gerwing, J., and R. Gelderman. 2001. Fertilizer recommendations guide. EC750. South Dakota State Univ., Coop. Ext. Serv., Brookings, SD.

Grant, C.A., E.H. Stobbe, and G.J. Racz. 1985. The effect of fall-applied N and P fertilizer and timing of N application on yield and protein content of winter wheat grown on zero-tilled land in Manitoba. Can. J. Soil Sci. 65:621–628.

Knowles, T.C., B.W. Hipp, P.S. Graff, and D.S. Marshall. 1994. Timing and rate of topdress nitrogen for rainfed winter wheat. J. Prod. Agric. 7:216–220.

McNeal, F.H., and D.J. Davis. 1954. Effect of nitrogen fertilization on yield, culm number, and protein content of certain spring wheat varieties. Agron. J. 46:375–378.[Free Full Text]

Microsoft Corporation. 1997. Microsoft Excel 97. Microsoft Corp., Redmond, WA.

Olson, R.A., K.D. Frank, E.J. Deibert, A.F. Dreier, D.H. Sander, and V.A. Johnson. 1976. Impact of residual mineral N in soil on grain protein yields of winter wheat and corn. Agron. J. 68:769–772.[Abstract/Free Full Text]

Partridge, J.R.D., and C.F. Shaykewich. 1972. Effects of nitrogen, temperature, and moisture regime on the yield and protein content of Neepawa wheat. Can. J. Soil Sci. 52:179–185.

Peltonen, J. 1992. Tissue nitrogen as a base for recommendations of additional nitrogen to spring wheat in southern Finland. Acta. Agric. Scand., Sect. B 42:164–169.

Pushman, F.M., and J. Bingham. 1976. The effects of a granular nitrogen fertilizer and a foliar spray of urea on the yield and bread-making quality of ten winter wheats. J. Agric. Sci. (Cambridge) 87:281–292.

SAS Institute. 1996. SAS for Windows. Version 6.12. SAS Inst., Cary, NC.

Simmons, S.R., E.A. Oelke, and P.M. Anderson. 1995. Growth and development guide for spring wheat. FO-2547-D. Minnesota Ext. Serv., St. Paul.

Stark, J.C., and T.A. Tindall. 1992. Timing split applications of nitrogen for irrigated hard red spring wheat. J. Prod. Agric. 5:221–226.

Strong, W.M. 1982. Effect of late application of nitrogen on the yield and protein content of wheat. Aust. J. Exp. Agric. Anim. Husb. 22:54–61.

Terman, G.L., R.E. Ramig, A.F. Dreier, and R.A. Olson. 1969. Yield–protein relationships in wheat grain as affected by nitrogen and water. Agron. J. 61:755–759.[Abstract/Free Full Text]

Vaughan, B., D.G. Westfall, and K.A. Barbarick. 1990. Nitrogen rate and timing effects on winter wheat grain yield, grain protein, and economics. J. Prod. Agric. 3:324–328.

Westcott, M. 1998. How to get higher spring wheat protein more efficiently. MT9806ag. Montana State Univ. Ext. Serv., Bozeman.

Wuest, S.B., and K.G. Cassman. 1992. Fertilizer-nitrogen use efficiency of irrigated wheat: I. Uptake efficiency of preplant versus late-season application. Agron. J. 84:682–688.[Abstract/Free Full Text]

This article has been cited by other articles:

J. U. H. Eitel, D. S. Long, P. E. Gessler, and E. R. Hunt
Combined Spectral Index to Improve Ground-Based Estimates of Nitrogen Status in Dryland Wheat
Agron. J., November 7, 2008; 100(6): 1694 - 1702.
[Abstract] [Full Text] [PDF]

B. N. Otteson, M. Mergoum, and J. K. Ransom
Seeding Rate and Nitrogen Management on Milling and Baking Quality of Hard Red Spring Wheat Genotypes
Crop Sci., March 19, 2008; 48(2): 749 - 755.
[Abstract] [Full Text] [PDF]

B. N. Otteson, M. Mergoum, J. K. Ransom, and B. Schatz
Tiller Contribution to Spring Wheat Yield under Varying Seeding and Nitrogen Management
Agron. J., February 29, 2008; 100(2): 406 - 413.
[Abstract] [Full Text] [PDF]

B. N. Otteson, M. Mergoum, and J. K. Ransom
Seeding Rate and Nitrogen Management Effects on Spring Wheat Yield and Yield Components
Agron. J., November 6, 2007; 99(6): 1615 - 1621.
[Abstract] [Full Text] [PDF]

K. D. Subedi, B. L. Ma, and A. G. Xue
Planting Date and Nitrogen Effects on Grain Yield and Protein Content of Spring Wheat
Crop Sci., January 22, 2007; 47(1): 36 - 44.
[Abstract] [Full Text] [PDF]

R. J. Kratochvil, M. R. Harrison Jr., J. T. Pearce, K. J. Conover, and M. Sultenfuss
Nitrogen Management for Mid-Atlantic Hard Red Winter Wheat Production
Agron. J., January 1, 2005; 97(1): 257 - 264.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Figures Only

Full Text (PDF) Free

Alert me when this article is cited

Alert me if a correction is posted

Services

Similar articles in this journal

Similar articles in ISI Web of Science

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (10)

Citing Articles via Google Scholar

Google Scholar

Articles by Bly, A. G.

Articles by Woodard, H. J.

Search for Related Content

PubMed

Articles by Bly, A. G.

Articles by Woodard, H. J.

Agricola

Articles by Bly, A. G.

Articles by Woodard, H. J.

Related Collections

Other Crop Management

Wheat

Plant Nutrition

Production Agriculture

The SCI Journals	Crop Science		Vadose Zone Journal
Journal of Natural Resources and Life Sciences Education		Soil Science Society of America Journal
Journal of Plant Registrations	Journal of Environmental Quality		The Plant Genome

				B. N. Otteson, M. Mergoum, and J. K. Ransom Seeding Rate and Nitrogen Management on Milling and Baking Quality of Hard Red Spring Wheat Genotypes Crop Sci., March 19, 2008; 48(2): 749 - 755. [Abstract] [Full Text] [PDF]

				B. N. Otteson, M. Mergoum, J. K. Ransom, and B. Schatz Tiller Contribution to Spring Wheat Yield under Varying Seeding and Nitrogen Management Agron. J., February 29, 2008; 100(2): 406 - 413. [Abstract] [Full Text] [PDF]

				K. D. Subedi, B. L. Ma, and A. G. Xue Planting Date and Nitrogen Effects on Grain Yield and Protein Content of Spring Wheat Crop Sci., January 22, 2007; 47(1): 36 - 44. [Abstract] [Full Text] [PDF]

				R. J. Kratochvil, M. R. Harrison Jr., J. T. Pearce, K. J. Conover, and M. Sultenfuss Nitrogen Management for Mid-Atlantic Hard Red Winter Wheat Production Agron. J., January 1, 2005; 97(1): 257 - 264. [Abstract] [Full Text] [PDF]