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Nitrate and ammonium losses from surface-applied organic and inorganic fertilizers

Published online by Cambridge University Press:  28 February 2007

K. W. KING  and
H. A. TORBERT
K. W. KING*
Affiliation:
USDA-ARS Soil Drainage Research, 590 Woody Hayes Drive, Columbus, OH 43210, USA
H. A. TORBERT
Affiliation:
USDA-ARS National Soil Dynamics Laboratory, 411 S. Donahue Dr., Auburn, AL 36832-5806, USA
*
*To whom all correspondence should be addressed. Email: [email protected]
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Summary

Animal manures are a valuable resource, providing readily available plant nutrients; however, runoff from lands receiving animal manure has been shown to contribute to water pollution. Understanding the loss of nutrients from slow release fertilizers, such as animal manure, after application is critical in determining and designing practices to reduce and/or control the temporal availability and potential offsite transport of NO3-N and NH4-N after application. A block study was designed to compare and contrast the temporal losses of NO3-N and NH4-N from three slow release fertilizers (sulphur-coated urea, composted dairy manure, and poultry litter) and one fast release fertilizer (ammonium nitrate) applied to bermudagrass (Cynodon dactylon L. Pers.) turf. Cumulative NO3-N loss from plots receiving application of the manufactured (NH4NO3 and sulphur-coated urea) products was significantly (P<0·05) greater than the measured losses from plots receiving application of natural products (composted dairy manure and poultry litter). The cumulative NO3-N recovered in the runoff expressed as a proportion of applied N was 0·37 for ammonium nitrate, 0·25 for sulphur-coated urea, 0·10 for composted dairy manure, and 0·07 for poultry litter during the 10-week study period. Cumulative NH4-N recovery fractions were an order of magnitude less than the cumulative NO3-N fractions and no significant differences (P>0·05) were measured across treatments. Significant differences (P<0·05) in NH4-N and NO3-N loss through time were measured for the four treatments. The findings of the present study indicate that land-applied animal manures are less susceptible to initial losses of N when compared to manufactured fertilizers.

Type
Crops and Soils
Information
The Journal of Agricultural Science , Volume 145 , Issue 4 , August 2007 , pp. 385 - 393
Copyright
Copyright © Cambridge University Press 2007

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References

REFERENCES

Aina, P. O. & Egolum, E. (1980). The effect of cattle feedlot manure and inorganic fertilizer on the improvement of subsoil productivity of Iwo soil. Soil Science 123, 212217.CrossRefGoogle Scholar
Bhadoria, P. B. S., Prakash, Y. S., Kar, S. & Rakshit, A. (2003). Relative efficacy of organic manures on rice production in lateritic soil. Soil Use and Management 19, 8082.CrossRefGoogle Scholar
Burns, J. C., Westerman, P. W., King, L. D., Overcash, M. R. & Cummings, G. A. (1987). Swine manure and lagoon effluent applied to a temperate forage mixture: I. Persistance, yield, quality, and elemental removal. Journal of Environmental Quality 16, 99105.CrossRefGoogle Scholar
Easton, Z. M. & Petrovic, A. M. (2004). Fertilizer source effect on ground and surface water quality in drainage from turfgrass. Journal of Environmental Quality 33, 645655.CrossRefGoogle ScholarPubMed
Edwards, D. R. & Daniel, T. C. (1994 a). A comparison of runoff quality effects of organic and inorganic fertilizers applied to fescuegrass plots. Water Resources Bulletin 30, 3541.CrossRefGoogle Scholar
Edwards, D. R. & Daniel, T. C. (1994 b). Organic and inorganic fertilizer effects on runoff water quality. Arkansas Farm Research 43, 45.Google Scholar
Eghball, B. (2000). Nitrogen mineralization from field-applied beef cattle feedlot manure or compost. Soil Science Society of America Journal 64, 20242030.CrossRefGoogle Scholar
Eghball, B. & Gilley, J. E. (1999). Phosphorus and nitrogen in runoff following beef cattle manure or compost application. Journal of Environmental Quality 28, 12011210.CrossRefGoogle Scholar
Gilley, J. E., Risse, L. M. & Eghball, B. (2002). Managing runoff following manure application. Journal of Soil and Water Conservation 57, 530533.Google Scholar
Heathman, G. C., Sharpley, A. N., Smith, S. J. & Robinson, J. S. (1995). Land application of poultry litter and water quality in Oklahoma, U.S.A. Fertilizer Research 40, 165173.CrossRefGoogle Scholar
Heathwaite, A. L., Griffiths, P. & Parkinson, R. J. (1998). Nitrogen and phosphorus in runoff from grassland with buffer strips following application of fertilizers and manures. Soil Use and Management 14, 142148.CrossRefGoogle Scholar
Huneycutt, H. J., West, C. P. & Phillips, J. M. (1988). Responses of Bermudagrass, Tall Fescue, and Tall Fescue-Clover to Broiler Litter and Commercial Fertilizer. Bulletin 913. Arkansas Agricultural Experiment Station, Fayetteville, AR: University of Arkansas.Google Scholar
Kleinman, P. J. A., Sharpley, A. N., Veith, T. L., Maguire, R. O. & Vadas, P. A. (2004). Evaluation of phosphorus transport in surface runoff from packed soil boxes. Journal of Environmental Quality 33, 14131423.CrossRefGoogle ScholarPubMed
Linde, D. T. & Watschke, T. L. (1997). Nutrients and sediment in runoff from creeping bentgrass and perennial ryegrass turfs. Journal of Environmental Quality 26, 12481254.CrossRefGoogle Scholar
Manugistics (2000). Statgraphics 5 Plus. Rockville, MD: Manugistics.Google Scholar
Marschner, P., Kandeler, E. & Marschner, B. (2003). Structure and function of the soil microbial community in a long-term fertilizer experiment. Soil Biology and Biochemistry 35, 453461.CrossRefGoogle Scholar
Masek, T. J., Schepers, J. S., Mason, S. C. & Francis, D. D. (2001). Use of precision farming to improve applications of feedlot waste to increase nutrient use efficiency and protect water quality. Communications in Soil Science and Plant Analysis 32, 13551369.CrossRefGoogle Scholar
McDowell, R. & Sharpley, A. N. (2002). Phosphorus transport in overland flow in response to position of manure application. Journal of Environmental Quality 31, 217222.CrossRefGoogle ScholarPubMed
McFarland, A. M. S. & Hauck, L. M. (1995). Livestock and the Environment: Scientific Underpinnings for Policy Analysis. PR95-01. Stephenville, TX: Texas Institute for Applied Environmental Research (TIAER), Tarleton State University.Google Scholar
McFarland, A. M. S. & Hauck, L. M. (1999). Relating agricultural land uses to in-stream stormwater quality. Journal of Environmental Quality 28, 836844.CrossRefGoogle Scholar
McLeod, R. V. & Hegg, R. O. (1984). Pasture runoff water quality from application of inorganic and organic nitrogen sources. Journal of Environmental Quality 13, 122126.CrossRefGoogle Scholar
Moss, B. R., Reeves, D. W., Lin, J. C., Torbert, H. A., McElhenney, W. H., Mask, P. & Kezar, W. (2001). Yield and quality of three corn hybrids as affected by broiler litter fertilization and crop maturity. Animal Feed Science and Technology 94, 4356.CrossRefGoogle Scholar
Owens, L. B., Edwards, W. M. & Van Keuren, R. W. (1984). Peak nitrate-nitrogen values in surface runoff from fertilized pastures. Journal of Environmental Quality 13, 310312.CrossRefGoogle Scholar
Plaza, C., Hernandez, D., Garcia-Gil, J. C. & Polo, A. (2004). Microbial activity in pig slurry-amended soils under semiarid conditions. Soil Biology and Biochemistry 36, 15771585.CrossRefGoogle Scholar
Pote, D. H., Reed, B. A., Daniel, T. C., Nichols, D. J., Moore, P. A. Jr., Edwards, D. R. & Formica, S. (2001). Water quality effects of infiltration rate and manure application rate for soils receiving swine manure. Journal of Soil and Water Conservation 56, 3237.Google Scholar
Santhi, C., Arnold, J. G., Williams, J. R., Hauck, L. M. & Dugas, W. A. (2001). Application of a watershed model to evaluate management effects on point and nonpoint source pollution. Transactions of the American Society of Agricultural Engineers 44, 15591570.CrossRefGoogle Scholar
Sauer, T. J., Daniel, T. C., Nichols, D. J., West, C. P., Moore, P. A. Jr. & Wheeler, G. L. (2000). Runoff water quality from poultry litter-treated pasture and forest sites. Journal of Environmental Quality 29, 515521.CrossRefGoogle Scholar
Schjonning, P., Elmholt, S., Munkholm, L. J. & Debosz, K. (2002). Soil quality aspects of humid sandy loams as influenced by organic and conventional long-term management. Agriculture, Ecosystems and Environment 88, 195214.CrossRefGoogle Scholar
Shirani, H., Hajabbasi, M. A., Afyuni, M. & Hemmat, A. (2002). Effects of farmyard manure and tillage systems on soil physical properties and corn yield in central Iran. Soil and Tillage Research 68, 101108.CrossRefGoogle Scholar
Singh, B., Rana, D. S., Kapur, M. L., Sharma, K. N. & Bhandari, A. L. (1983). Evaluation of farmyard manure applied along with fertilizers to maize (Zea mays L.) and wheat (Triticum aestivum L.). Indian Journal of Agronomy 3, 285289.Google Scholar
Smith, K. A., Jackson, D. R. & Pepper, T. J. (2001). Nutrient losses by surface run-off following the application of organic manures to arable land. 1. Nitrogen. Environmental Pollution 112, 4151.CrossRefGoogle ScholarPubMed
Sweeten, J. M. & Mathers, A. C. (1985). Improving soils with livestock manure. Journal of Soil and Water Conservation 40, 206210.Google Scholar
Tarkalson, D. D. & Mikkelsen, R. L. (2004). Runoff phosphorus losses as related to phosphorus source, application method, and application rate on a Piedmont soil. Journal of Environmental Quality 33, 14241430.CrossRefGoogle ScholarPubMed
Technicon Industrial Systems (1973 a). Nitrate and Nitrite in Water and Waste Water. Industrial method no. 100-70w. Tarrytown, NY: Technicon Instruments Corp.Google Scholar
Technicon Industrial Systems (1973 b). Ammonia in Water and Waste Water. Industrial method no. 98-70w. Tarrytown, NY: Technicon Instruments Corp.Google Scholar
Technicon Industrial Systems (1976). Individual/simultaneous Determination of Nitrogen and/or Phosphorus in BD Acid Digest. Industrial method no. 344-74a. Tarrytown, NY: Technicon Instruments Corp.Google Scholar
The Composting Council (1996). Field Guide to Compost Use. Alexandria, VA: The Composting Council.Google Scholar
Torbert, H. A., Potter, K. N. & Morrison, J. E. Jr. (1996). Management effects on nitrogen and phosphorus losses in runoff on expansive clay soils. Transactions of the American Society of Agricultural Engineers 39, 161166.CrossRefGoogle Scholar
Torbert, H. A., Potter, K. N., Hoffman, D. W., Gerik, T. J. & Richardson, C. W. (1999). Surface residue and soil moisture affect fertilizer loss in simulated runoff on a heavy clay soil. Agronomy Journal 91, 606612.CrossRefGoogle Scholar
Wienhold, B. J. (2005). Changes in soil attributes following low phosphorus swine slurry application to no-tillage sorghum. Soil Science Society of America Journal 69, 206214.CrossRefGoogle Scholar
Yang, S. M., Li, F. M., Mahli, S. S., Wang, P., Suo, D. R. & Wang, J. G. (2004). Long-term fertilizer effects on crop yield and nitrate nitrogen accumulation in soil in northwestern China. Agronomy Journal 96, 10391049.CrossRefGoogle Scholar