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Factors influencing nitrogen mineralization during poultry litter composting and calculations for available nitrogen

Published online by Cambridge University Press:  18 September 2007

K.H. Nahm
Affiliation:
Feed and Nutrition Laboratory, College of Natural Resources, Taegu University, Gyong San, 712–714, South Korea E-mail:NahmKH@Daegu.ac.kr
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Abstract

This paper describes, under laboratory and/or field conditions, an approach that could be used to predict nitrogen (N) mineralization of poultry litter. Proper composting of poultry litter results in N mineralization, reducing or eliminating the environmentally harmful effects of ammonia (NH3) odours and nitrate leaching. Addition of straw to poultry manure provides sufficient available carbon and increases NH3 binding capacity, overruling any greater influence of diet composition on methane (CH3) formation. C:N ratio ranges (6–25) vary in the amount of low N loss depending on substrates. Aerobic decomposition of manure results in formation of humified organic compounds and decreased nutrient availability, while anaerobic decomposition forms low molecular weight compounds (volatile fatty acids and NH3+- N). The differences in the size of the composted particles results in physical separation and decomposability of high and low C:N ratio substrates. Temperatures ranging from 14 to 35°C did not affect the rate of N mineralization, but affected N loss from poultry manure pellets by decay nitrification at 14 and 35°C compared with 25°C. Uric acid and undigested proteins in poultry litter have optimal degradation rates at pH of 5.5 or higher, with the optimum pH for uricase being about 9. Variations in manure composition are seen between different species such as cattle, swine and poultry. The chemical composition of the manure and not the substrate N status influences the rate of decomposition or microbial availability. The N mineralization potential of some vegetable residues correlated better with the total and water soluble N contents than with their C:N ratios. Poultry manures are applied to agricultural soils at rates determined by the amount of available N that they are assumed to contribute to the crops. Many equations have been developed to calculate these application rates.

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Copyright © Cambridge University Press 2005

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References

Acharya, C.N. (1935) Studies on the anaerobic decomposition of plant materials. I. The anaerobic decomposition of rice straw. Biochemistry Journal 29: 528541.CrossRefGoogle ScholarPubMed
Alexander, M. (1977) Nitrification. In: Introduction to Soil Microbiology (2nd Ed.). John Wiley and Sons, Inc., New York, NY, USA. Pp. 225250.Google Scholar
Al-Kanani, T., Akochi, E., Mac Kenize, A.F., Alli, I., Anderson, D.W., Heil, R.D., Cole, C.V. and Deutsh, P.C. (1983) Identification and characterization of ecosystems at different integrative levels. In: Nutrient Cycling in Agricultural Ecosystems (Lowance, R. et al. , Eds.). University of Georgia, College of Agriculture, Experiment Station, September. Publication 23. pp. 517531.Google Scholar
Barbarika, A. Jr., Sikora, L.J. and Colacicco, D. (1985) Factors affecting the mineralization of nitrogen of sewage sludge applied to soils. Soil Science Society of America Journal 49: 14031411.CrossRefGoogle Scholar
Beck, J., Kock, M., Hentschel, T., Csehi, K. and Jungbluth, T. (1997) Ammonia emissions from composting animal wastes in reactors and windows. In: Ammonia and Odour Emission from Animal Production Facilities. International Conference Proceedings (Voermans, J.A.M., Monteny, G.J., Eds.). Vinkeloord, The Netherlands: Dutch Society of Agricultural Engineering. Pp. 381388.Google Scholar
Bernal, M.P. and Kirchmann, H. (1992) Carbon and nitrogen mineralization and ammonia volatilization from fresh, aerobically and anaerobically treated pig manure during incubation with soil. Biological Fertilization and Soils 13: 135141.CrossRefGoogle Scholar
Bitzer, C.C. and Sims, J.T. (1988) Estimating the availability of nitrogen in poultry manure through laboratory and field studies. Journal of Environmental Quality 17: 4754.CrossRefGoogle Scholar
Burnett, W.E. and Dondero, N.C. (1969) Microbiological and chemical changes in poultry manure associated with decomposition and odour generation. In: Animal Waste Management, Proceedings of Cornell University Conference of Agriculture Waste Management. Pp. 271–274.Google Scholar
Carlile, F.S. (1984) Ammonia in poultry houses: A literature review. World's Poultry Science Journal 40: 99113.CrossRefGoogle Scholar
Castellanos, J.Z. and Pratt, P.F. (1981) Mineralization of manures nitrogen correlation with laboratory indexes. Soil Science Society of America Journal 45: 354357.CrossRefGoogle Scholar
Chadwick, D.R., John, F., Pain, B.F., Chambers, B.J. and Williams, J. (2000) Plant uptake of nitrogen from the organic nitrogen fraction of animal manures: A laboratory experiment. Journal of Agricultural Science 134: 159168.CrossRefGoogle Scholar
Collins, H.P., Elliot, L.F., Rickmann, R.W., Bezdieek, D.F. and Papendick, R.I. (1990) Decomposition and interactions among wheat residue components. Soil Science Society of America Journal 54: 780785.CrossRefGoogle Scholar
Cooper, P. and Cornforth, I.S. (1978) Volatile fatty acids in stored animal slurry. Journal of Science Food and Agriculture 29: 1927.CrossRefGoogle Scholar
De Silva, A.P. and Breitenbeck, G.A. (1997) Nitrogen enrichment of wastes by ammoniation. Journal of Environmental Quality 26: 688694.CrossRefGoogle Scholar
Douglas, B.F. and Magdoff, F.R. (1991) An evaluation of nitrogen mineralization induces for organic residues. Journal of Environmental Quality 20: 368372.CrossRefGoogle Scholar
Ehlhardt, D.A. and Janssen, W.M.M.A. (1987) A View on Chicken Manure. COVP, Spelderholt, Beekbergen, The Netherlands. p. 38.Google Scholar
Elliot, H.A. and Collins, N.E. (1983) Chemical methods for controlling ammonia release from poultry manure. ASAE. Paper 83–4521, p. 17.Google Scholar
Elwomger, K. and Svensson, L. (1996) Effect of dietary protein content, litter and drinker type on ammonia emission from broiler houses. Journal of Agricultural Engineering Research 64: 197208.CrossRefGoogle Scholar
Epstein, E., Keen, D.B., Meisinger, J.J. and Legg, J.D. (1978) Mineralization of nitrogen from sewage sludge and sludge compost. Journal of Environmental Quality 7: 217221.CrossRefGoogle Scholar
Flachowsky, G. and Hennig, A. (1990) Composition and digestibility of untreated and chemically treated animal excreta for ruminants – A review. Biological Wastes 31: 1736.CrossRefGoogle Scholar
Floate, M.S. (1970) Decomposition of organic materials from hill soils and pastures. II. Comparative studies on carbon, nitrogen and phosphorus from plant materials and sheep faces. Soil Biology and Biochemistry 2: 173185.CrossRefGoogle Scholar
Gale, P.M. and Gilmour, J.T. (1986) Carbon and nitrogen mineralization kinetics for poultry litter. Journal of Environmental Quality 15 (4): 423426.CrossRefGoogle Scholar
Gilmore, E.C. Jr. and Rogers, J.S. (1958) Heat units as a method of measuring maturity in corn. Agronomy Journal 50: 611615.CrossRefGoogle Scholar
Gilmour, J.T. (1998) Carbon and nitrogen mineralization during coutilization of biosolids and composts. In: Beneficial Co-utilization of Agriculture, Municipal and Industrial By-products (Brown, S. et al. , Ed.), Kluwer Academic Publ., Dordrecht, The Netherlands. Pp. 89112.CrossRefGoogle Scholar
Gilmour, J.T., Clark, M.D. and Sigua, G.C. (1985) Division s-3-soil microbiology and biochemistry. Soil Science Society of America Journal 49: 13981402.CrossRefGoogle Scholar
Gilmour, J.T. and Skinner, V. (1999) Predicting plant available nitrogen in land-applied biosolids. Journal of Environmental Quality 28: 11221126.CrossRefGoogle Scholar
Glenn, J. (1998) Dairy farm thrives with manure composting. Biocycle 39: 40.Google Scholar
Gordillo, R.M. and Cabrera, M.L. (1997) Mineralizable nitrogen in broiler litter. I. Effect of selected litter chemical characteristics. Journal of Environmental Quality 26: 16721681.CrossRefGoogle Scholar
Griffin, D.M. (1981) Water and microbial stress. In: Advances in Microbial Ecology, New York: Plenum Press. Pp. 91136.CrossRefGoogle Scholar
Grootkoerkamp, P.W.G. (1994) Review on emissions of ammonia from housing systems for laying hens in relation to sources, processes, building design and manure handling. Journal of Agricultural Research 59: 7387.Google Scholar
Hadas, A., Bar-Yoseff, B., Davidov, S. and Sofer, M. (1983) Effect of pelleting, temperature, and soil type on mineral nitrogen release from poultry and dairy manures. Soil Science Society of America Journal 47: 11291133.CrossRefGoogle Scholar
Harper, S.H.T. and Lynch, J.M. (1981) The chemical components and decomposition of wheat straw leaves, internodes and nodes. Journal of Science and Food Agriculture 32: 10571062.CrossRefGoogle Scholar
Herman, W.A., McGill, W.B. and Dormaar, J.F. (1977) Effects of initial chemical composition on decomposition of roots of three grass species. Canadian Journal of Soil Science 57: 205215.CrossRefGoogle Scholar
Honeycutt, C.W. and Potaro, L.J. (1990) Field evaluation of heat units for predicting crop residue carbon and nitrogen mineralization. Plant and Soil 125: 213220.CrossRefGoogle Scholar
Honeycutt, C.W., Zibilske, L.M. and Clapham, W.M. (1988) Heat units for describing carbon mineralization and predicting net nitrogen mineralization. Soil Science Society of America Journal 52: 13461350.CrossRefGoogle Scholar
Hsieh, Y.P., Douglas, L.A. and Motto, H.L. (1987) Modelling sewage sludge decomposition in soil: Nitrogen transformations. Journal of Environmental Quality 10: 5964.CrossRefGoogle Scholar
Huff, W.E., Malone, G.W. and Chaloupka, G.W. (1984) Effect of litter treatment on broiler performance and certain litter quality parameters. Poultry Science 63: 21672171.CrossRefGoogle ScholarPubMed
Iritani, W.M. and Arnold, C.Y. (1960) Nitrogen release vegetable crop residues during incubation as related their chemical composition. Soil Science 89: 7482.CrossRefGoogle Scholar
Jansson, S.L. and Clark, F.E. (1952) Losses of nitrogen during decomposition of plant material in the presence of inorganic nitrogen. Soil Science Society Proceedings 16: 330334.CrossRefGoogle Scholar
Jansson, S.L. and Persson, J. (1982) Mineralization and immobilization of soil nitrogen. In: Nitrogen in agricultural soils (Stevenson, F.J., Ed.). Agronomy 22: 229252.Google Scholar
Janzen, H.H. and Kucey, R.M.N. (1988) C, N and S mineralization of crop residues as influenced by crop species and nutrient regime. Plant and Soil 106: 3541.CrossRefGoogle Scholar
Jeong, K.H., Kim, T.I., Choi, K.C., Han, J.D. and Kim, W.H. (1997) Changes of compost properties during aerobic composting of poultry manures. Korean Journal of Animal Science 39 (6): 731738.Google Scholar
Kirchmann, H. (1985) Losses, plant uptake and utilization of manure nitrogen during a production cycle. Acta Agriculture Scandinavia 24 (Suppl.): 57.Google Scholar
Kirchmann, H. (1989) A 3–year N balance study with aerobic, anaerobic and fresh 15N-labeled poultry manure. In: Nitrogen in Organic Wastes Applied to Soils (Hansen, J.A. and Henriksen, K., Eds.). Academic Press, London, UK. Pp. 113125.Google Scholar
Kirchmann, H. and Witter, E. (1989) Ammonia volatilization during aerobic and anaerobic manure decomposition. Plant and Soil 115: 3541.CrossRefGoogle Scholar
Klausner, S.D. and Guest, R.W. (1981) Influence of ammonia conservation from dairy manure on the yield of corn. Agronomy Journal 73: 720723.CrossRefGoogle Scholar
Klausner, S.D., Rao Kanneganti, V. and Bouldin, D.R. (1994) An approach for estimating a decay series for organic nitrogen in animal manure. Agronomy Journal 86: 897903.CrossRefGoogle Scholar
Knapp, E.B., Elliott, L.F. and Campbell, G.S. (1983) Microbial respiration and growth during the decomposition of wheat straw. Soil Biology & Biochemistry 15: 455461.CrossRefGoogle Scholar
Kolenbrander, G.J. (1981) Limits to the spreading of animal excrement on agricultural land. In: Nitrogen Losses and Surface Run-off Land Spread Manures (Brogen, J.C., Ed.). Nijhoff/Junk CEC. The Hague, 433–68. UK.Google Scholar
Kulling, D.R., Menzi, H., Krober, T.F., Neftel, A., Sutter, F., Lischer, P. and Kreuzer, M. (2001) Emissions of ammonia, nitrous oxide and methane from different types of dairy manure during storage as affected by dietary protein content. Journal of Agricultural Science 137: 235250.CrossRefGoogle Scholar
Leenstra, F. and Pit, R. (1990) Strain differences in water content of dropping of laying hens. Proceedings of 8th European Poultry Conference, 25–28 June. Closas, A. (Ed.). Barcelona, Spain. Pp. 435438.Google Scholar
Lerch, R.N., Barbarick, K.A., Sommers, L.E. and Westfall, D.G. (1992) Sewage sludge proteins as labile carbon and nitrogen sources. Soil Science of America Journal 56: 14701476.CrossRefGoogle Scholar
Levi-Minzi, R., Riffaldi, R. and Saviozzi, A. (1986) Organic matter and nutrients in fresh and mature farmyard manure. Biology and Wastes 16: 225236.CrossRefGoogle Scholar
Levi-Minzi, R., Riffaldi, R. and Saviozzi, A. (1990) Carbon mineralization in soil amended with different organic materials. Agriculture Ecosystems and Environment 31: 325335.CrossRefGoogle Scholar
Lory, J., Adams, J., Eghball, B., Klopfenstein, T. and Powers, J.F. (2002) Effects of adding sawdust and acidification for steers production. Nebraska Beef Report 2. In: Sawdust application may reduce nitrogen losses from dry feedlots (Lundeen, T., Ed.), Feedstuff 74 (9): 9 and 11.Google Scholar
Lupway, N.Z. and Haque, Z. (1998) Mineralization of N, P, K, Ca and Mg from sesbania and leucaena leaves varying in chemical composition. Soil Biology and Biochemistry 30: 337344.CrossRefGoogle Scholar
Maas, F.E. and Adamson, R.M. (1972) Resistance of sawdusts, peats and bark to decomposition in the presence of soil and nutrient solution. Soil Science Society of America Journal 36: 769772.CrossRefGoogle Scholar
Maeda, T. and Matsuda, J. (1997) Ammonia emissions from composting livestock manure. In: Ammonia and Odour Emissions from Animal Production Facilities, International Conference Proceedings (Voermans, J.A.M. and Monteny, G.J., Eds.). Vinkeloord, The Netherlands. Dutch Society of Agricultural Engineering. Pp. 145153.Google Scholar
Magdoff, F. (1978) Influence of manure application rates and continuous corn on soil N. Agronomy Journal 70: 629632.CrossRefGoogle Scholar
Magdoff, F.R. and Chromec, F.W. (1977) Nitrogen mineralization from sewage sludge. Journal of Environmental Science and Health, Part A 12: 191201.Google Scholar
Mary, B. and Recous, S. (1994) Measurement of nitrogen mineralization and immobilization flues in soil as a means of predicting net mineralization. European Journal of Agronomy 3: 110.CrossRefGoogle Scholar
Mathers, A.C. and Goss, D.W. (1979) Estimating animal waste applications to supply crop nitrogen requirements. Soil Science Society of America Journal 43: 364366.CrossRefGoogle Scholar
Melillo, J.M. and Aber, J.D. (1982) Nitrogen and lignin control of hardwood leaf litter decomposition dynamics. Ecology 63: 621634.CrossRefGoogle Scholar
Ministry of Agriculture, Fisheries and Food (1986) Profitable Use of Farm Manures. ADAS Booklet 2081. HMSO, London, UK.Google Scholar
Molloy, S.P. and Tunney, H. (1983) A laboratory study of ammonia volatilization from cattle and pig slurry. Irish Journal of Agriculture 22: 3745.Google Scholar
Moore, P.AP Jr., Daniel, T.C., Edwards, D.R. and Miller, D.M. (1995) Effect of chemical amendments on ammonia volatilization from poultry litter. Journal of Environmental Quality 24: 293320.CrossRefGoogle Scholar
Mueller, T., Jensen, L.S., Nielsen, N.E. and Magid, J. (1998) Turnover of carbon and nitrogen in a sandy loams soil following incorporation of chopped maize plants, barley straw and blue grass in the field. Soil Biology and Biochemistry 30: 561571.CrossRefGoogle Scholar
Nahm, K.H. (2003a) Evaluation of the nitrogen content in poultry manure. World's Poultry Science Journal 59: 7788.CrossRefGoogle Scholar
Nahm, K.H. (2003b) Current pollution and odour control technologies for poultry production. Avian and Poultry Biology Review 14 (4): 131155.CrossRefGoogle Scholar
Noborg, M. (1969) Fixation of gaseous ammonium by soils. Soil Science 107: 131136.CrossRefGoogle Scholar
Nommik, H. (1970) Non-exchangeable binding of ammonium and amino acid nitrogen by Norway spruce raw humus. Plant Soil 33: 581595.CrossRefGoogle Scholar
Pain, B.F., Smith, K.A. and Dyer, C.T. (1986) Factors affecting the response of cut grass to the nitrogen content of dairy cows slurry. Agricultural Wastes 17: 189202.CrossRefGoogle Scholar
Parker, M.B., Perkins, H.F. and Fuller, H.L. (1959) Nitrogen, phosphorus and potassium content of poultry manure and some factors influencing its composition. Journal Paper No. 68 of the College Experiment Station, University of Georgia, GA, USA. Pp. 11541158.Google Scholar
Parker, C.F. and Sommers, L.E. (1983) Mineralization of nitrogen in sewages. Journal of Environmental Quality 12: 150156.CrossRefGoogle Scholar
Parr, J.F. and Papendick, R.I. (1978) Factors affecting the decomposition of crop residues by microorganisms. In: Crop Residue Management Symposium (Oschwald, W.R., Ed.). ASA, CSSA, SSSA, Madison, WI, USA. Pp. 101129.Google Scholar
Parsons, A.H. and Baker, S.I.. (1985) Soft wood chipping fines: Efficacy as poultry litter. Poultry Science 64: 22922295.CrossRefGoogle Scholar
Powers, W.L., Wallingford, G.W. and Murphy, L.S. (1975) Formulas for applying organic wastes to land. Journal of Soil Science and Water Conservation 30: 286289.Google Scholar
Pratt, P.F., Broadbent, F.E. and Martin, J.P. (1973) Using organic wastes as nitrogen fertilizers. California Agriculture 27 (6): 1013.Google Scholar
Pratt, P.F., Davis, S. and Sharpless, R.G. (1976) Afour year trial with manures. Hilgardia 44: 99125.CrossRefGoogle Scholar
Premi, P.R. and Cornfield, H. (1971) Incubation study of nitrogen mineralization of soil treated with dry sewage sludge. Environmental Pollution 2: 15.Google Scholar
Quemada, M. and Cabrera, M.L. (1995) Carbon and nitrogen mineralized from leaves and stems of four cover crops. Soil Science Society of America Journal 59: 471477.CrossRefGoogle Scholar
Reinertsen, S.A., Elliott, L.F., Cochran, V.L. and Campbell, G.S. (1984) Role of available carbon and nitrogen in determining the rate of wheat straw decomposition. Soil Biology and Biochemistry 16: 459466.CrossRefGoogle Scholar
Riffaldi, R., Saviozzi, A., and Levi-Minzi, R. (1996) Carbon mineralization kinetics as influenced by soil properties. Biological Fertilization and Soils 22: 293298.CrossRefGoogle Scholar
Rubins, E.J. and Bear, F.E. (1942) Carbon-nitrogen ratios in organic fertilizer materials in relation to the availability of their nitrogen. Soil Science 4: 411423.CrossRefGoogle Scholar
Russell, E.J. and Richards, E.H. (1917) The changes taking place during the storage of farmyard manure. Journal of Agricultural Science 8: 495552.CrossRefGoogle Scholar
Ryan, J.A., Keeney, D.R. and Walsh, L.M. (1973) Nitrogen transformations and availability of anaerobically digested sewage sludge in soil. Journal of Environmental Quality 2: 489492.CrossRefGoogle Scholar
Ryden, J.C. (1984) The flow of nitrogen in grassland. Proceedings of Fertilization SocietyLondon, UK. No. 229.Google Scholar
Sabey, B.R. (1977) Availability and transformation of sewage nitrogen. In: Food, Fertilizer and Agricultural Residues (Loehr, R.C., Ed.). Ann Arbor Science Publishers, Ann Arbor, Michigan, USA. Pp. 257269.Google Scholar
Sain, P. and Broadbent, F.E. (1977) Decomposition of rice straw in soil as affected by some management factors. Journal of Environmental Quality 6 (1): 96100.CrossRefGoogle Scholar
Schefferle, H.E. (1965) The decomposition of uric acid in built up poultry manure. Journal of Applied Bacteriology 28: 412420.CrossRefGoogle Scholar
Serna, M.D. and Pomares, F. (1991) Comparison of biological and chemical methods to predict nitrogen mineralization in animal wastes. Biological and Fertilized Soils 12: 8994.CrossRefGoogle Scholar
Serna, M.D. and Pomares, F. (1992) Indexes of assessing N availability in sewage sludges. Plant Soil 139: 1521.CrossRefGoogle Scholar
Sims, J.T. (1986) Nitrogen transformations in a poultry manure amended soil: Temperature and moisture effects. Journal of Environmental Quality 15: 5763.CrossRefGoogle Scholar
Snyder, J.M., Rowoth, O.A., Scholes, J.C. and Lee, C.E. (1985) Profitable Poultry Management, 23 Ed., pp. 7983, Published by Ward Lock & Co., Ltd., Melbourne, Australia.Google Scholar
Spoelstra, S.F. (1979) Volatile fatty acids in anaerobically stored piggery wastes. Netherlands Journal of Agricultural Science 27: 6066.CrossRefGoogle Scholar
Stanford, G., Frere, M.H. and Schwaninger, D.H. (1973) Temperature coefficient of soil nitrogen mineralization. Soil Science 115: 321323.CrossRefGoogle Scholar
Stephenson, R.J. (1955) Availability of nitrogen in sewage sludges. Sewage and Industrial Wastes 27: 3439.Google Scholar
Subair, S., Fylets, J.W. and O'Halloran, I.R. (1999) Ammonia volatilization from liquid hog manure amended with paper products in the laboratory. Journal of Environmental Quality 28: 202207.CrossRefGoogle Scholar
Terry, R.E., Nelson, D.W. and Sommers, L.E. (1981) Nitrogen transformation in sewage sludgeamended soils as affected by soil environmental factors. Soil Science Society of America Journal 45: 506513.CrossRefGoogle Scholar
Tester, C.F., Sikora, L.J., Taylor, J.M. and Parr, J.F. (1977) Decomposition of sewage sludge composition in soil: I. Carbon and nitrogen transformation. Journal of Environmental Quality 6: 459468.CrossRefGoogle Scholar
Thomsen, I.K. and Kjellerup, V. (1997) Yields and N uptake of barley and ryegrass from soils with added animal manure differing in straw and urine content. European Journal of Agronomy 7: 285292.CrossRefGoogle Scholar
U.S. Environmental Protection Agency (1995) Process design manual-land application of sewage and domestic septage. USEPA/625/R-95/001. USEPA, Office of Research and Development, Washington, DC, USA.Google Scholar
Van Faassen, H.G. and Van Dijk, H. (1987) Manure as a source of nitrogen and phosphorus in soils. In: Animal Manures on Grassland and Fodder Crops (van der Meer, H.G., Ed.), Dordrecht, Netherlands: Martinus Nijhoff Publishers. Pp. 2744.Google Scholar
Van Kessel, J.S., Reeves, J.B. III. and Meisings, J.J. (2000) Nitrogen and carbon mineralization of potential manure components. Journal of Environmental Quality 29: 16691677.CrossRefGoogle Scholar
Vogels, G.D. and van der Drift, C. (1976) Degradation of purines and pyrimidines by microorganisms. Bacteriological Reviews 40: 403468.CrossRefGoogle ScholarPubMed
Weast, R.C., Astle, M.J. and Beyer, W.H. (1986) Handbook of Chemistry and Physics. 67th edition, CRC Press, Florida, USA. Pp. D-163.Google Scholar
Whitehead, D.C., Bristow, A.W. and Pain, B.F. (1989) The influence of some cattle and pig slurries on the uptake of nitrogen by ryegrass in relation to fractionation on the sturry N. Plant and Soil 117: 111120.CrossRefGoogle Scholar