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The phosphorus cycle in pig slurry measured from 32PO4 distribution rates

Published online by Cambridge University Press:  27 March 2009

R. G. Gerritse  and
I. Zugec
R. G. Gerritse
Affiliation:
Institute for Soil Fertility, Haren (Gr.), The Netherlands
I. Zugec
Affiliation:
Institute for Soil Fertility, Haren (Gr.), The Netherlands
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Summary

The rate of isotopic distribution of labelled phosphorus, added as H332PO4, between inorganic and organic phosphates and phosphates contained in micro-organisms was measured in pig slurry. Incorporation of 32P in all these phosphates occurred quickly in both aerated and non-aerated pig slurry. On the basis of a simplified model, turnover times for phosphorus were calculated to be of the order of 10–20 weeks for both non-aerated and aerated pig slurry.

Pig slurry contains 1–2% P (of dry matter) of which 10–30% is in organic molecules and 2–3% is in micro-organisms. About 10–20% of the organic phosphates is in solution, amounting to 10–20 mg P/l. The concentration of inorganic P in solution is of the order of 10–100 mg/1 though, at low Ca/P ratios in the feed, can be as high as 1000 mg/1.

Organic phosphates in solution in pig slurry are of high molecular weight and probably consist of DNA complexes with polyphosphates, Ca and (if used in the feed) Cu.

It is concluded that all organic phosphates in pig slurry are of microbial origin and that the feed composition has little influence on the organic phosphate content of the slurry.

Arguments for application of the results to pig slurry in general and to wastes from other animals are given.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 88 , Issue 1 , February 1977 , pp. 101 - 109
Copyright
Copyright © Cambridge University Press 1977

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References

Barrow, N. J. (1975). Chemical forms of inorganic phosphate in sheep faeces. Australian Journal of Soil Research 13, 63–7.CrossRefGoogle Scholar
Bromfield, S. M. (1961). Sheep faeces in relation to the phosphorus cycle under pasture. Australian Journal of Agricultural Research 12, 111–23.CrossRefGoogle Scholar
Caldwell, A. G. & Black, C. A. (1958). Inositolhexaphosphate: 1. Determination in extracts of soils and manures. 2. Synthesis by microorganisms. Soil Science Society of America, Proceedings 22, 290–6.CrossRefGoogle Scholar
Campbell, L. B. & Racz, G. J. (1975). Organic and inorganic P content, movement and mineralization in soil beneath a feedlot. Canadian Journal of Soil Science 55, 457–66.CrossRefGoogle Scholar
Erickson, A. E., Ellis, B. G. & Tiedje, I. M. (1975). Soil modification for denitrification and phosphate reduction of feedlot waste. Washington, Office of Research and Development, U.S. Environmental Protection Agency (EPA 660/2–74–057).Google Scholar
Fuhs, G. W. & Chen, W. (1975). Microbiological basis of phosphate removal in the activated sludge process for the treatment of waste water. Microbial Ecology 2, 119–38.CrossRefGoogle Scholar
Goodrich, P. (1970). Movement of pollutant phosphorus in saturated soils. Thesis, Purdue University.Google Scholar
Hannapel, R. J., Fuller, W. H. & Bosma, S. (1963). Phosphorus movement in a calcareous soil: 1. Predominance of organic forms of phosphorus in phosphorus movement. Soil Science 97, 350–7.CrossRefGoogle Scholar
Hannapel, R. J., Fuller, W. H. & Fox, R. H. (1963). Phosphorus movement in a calcareous soil: 2. Soil microbial activity and organic P movement. Soil Science 97, 421–7.CrossRefGoogle Scholar
Hayes, F. R. & Phillips, J. E. (1958). Radiophosphorus equilibrium with mud, plants and bacteria. Limnology and Oceanography 3, 459–75.CrossRefGoogle Scholar
Hodson, P. H. (1973). The role of phosphorus in bacteria and viruses. In Environmental Phosphorus Handbook (ed. Griffith, E. J., Beeton, G., Spencer, J. M. and Mitchell, D. T.), pp. 451–74. New York: Wiley Interscience.Google Scholar
Hooper, F. F. (1973). Origin and fate of organio phosphorus compounds in aquatic systems. In Environmental Phosphorus Handbook (ed. Griffith, E. J., Beeton, G., Spencer, J. M. and Mitchell, D. T.), pp. 179202. New York: Wiley Interscience.Google Scholar
Kakàč, B. & VedjdĔlek, Z. J. (1974). Handbuch der photometrische Analyse organischer Verbindungen, Band 2. Weinheim: Verlag Chemie.Google Scholar
Larsen, S. (1968). The influence of soil organic matter on loss of available phosphate in soil by chemical reactions. In Isotopes and Radiation in Soil-Organic Matter Studies, pp. 377–82. Vienna: International Atomic Energy Agency.Google Scholar
McAliffe, C. & Peech, M. (1949). Utilization by plants of phosphorus in farm manure: 1. Labelling of phosphates in sheep manure with 32P. Soil Science 68, 179–95.CrossRefGoogle Scholar
Murphy, J. & Rlley, J. P. (1962). A modified single solution method for the determination of phosphate in natural waters. Analytica Chimica Ada 27, 31–6.CrossRefGoogle Scholar
O'Kelley, J. C. (1973). Phosphorus nutrition of algae. In Environmental Phosphorus Handbook (ed. Griffith, E. J., Beeton, G., Spencer, J. M. and Mitchell, D. T.), pp. 443–50. New York: Wiley Interscience.Google Scholar
Pepebzak, P., Caldwell, A. G., Hunziker, R. R. & Black, C. A. (1959). Phosphorus fractions in manures. Soil Science 87, 293302.CrossRefGoogle Scholar
Pomeroy, R. L., Smith, E. E. & Grant, M. G. (1965). The exchange of phosphate between estuarine water and sediments. Limnology and Oceanography 2, 167–72.CrossRefGoogle Scholar
Rameau, J. Th. L. B. & Ten Have, J. (1950). Photometric determination of phosphorus in soils and plant material. Chemisch Weekblad 47, 1005–13.Google Scholar
Rolston, D. E., Rauschkolb, R. S. & Hoffmann, D. L. (1975). Infiltration of organic phosphate compounds in soil. Soil Science Society of America. Proceedings 39, 1089–94.CrossRefGoogle Scholar
Sauerlandt, W. (1960). Phosphor in Stalldünger. Landwirtschaftliche Forschung, Sonderheft 14, 3843.Google Scholar
Scharpf, L. C. (1973). Transformations of naturally occurring organo-phosphorus compounds in the environment. In Environmental Phosphorus Handbook (ed. Griffith, E. J., Beeton, G., Spencer, J. M. and Mitchell, D. T.), pp. 393412. New York: Wiley Interscience.Google Scholar
Schlegel, H. G. (1972). Allgemeine Mikrobiologie. Stuttgart: Georg Thieme Verlag.Google Scholar
Tinsley, J. & Özsavasci, C. (1975). Studies of soil organic phosphorus using titanic chloride. Transactions of the 10th International Congress of Soil Science, vol. II, 332–40.Google Scholar