Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-24T21:47:16.872Z Has data issue: false hasContentIssue false
  • English
  • Français

pH and buffer component dynamics in the surface layers of animal slurries

Published online by Cambridge University Press:  27 March 2009

S. G. Sommer  and
R. R. Sherlock
S. G. Sommer
Affiliation:
Department of Soil Science, Danish Institute of Plant and Soil Science, Research Centre Foulum, PO Box 23, DK-8830 Tjele, Denmark
R. R. Sherlock
Affiliation:
Department of Soil Science, PO Box 84, Lincoln University, Canterbury, New Zealand
Get access Rights & Permissions [Opens in a new window]

Summary

The changes in the buffer components and pH in the surface layer of a pig and a cattle slurry were studied in the laboratory of the Department of Soil Science, Lincoln University in 1994. The slurries were spread to a depth of 7 mm in Petri dishes open to the atmosphere. Slurry pH, total inorganic carbon (TIC = CO2 + HCO- + H2CO3), total ammoniacal nitrogen (TAN = NH3 + NH4+) and volatile fatty acids (VFA = C2-C5 acids) were determined at 8–10 intervals after 1–96 h of incubation at 10, 16 and 22 °C. A great increase in pH over the first 8 h was due to the release of CO2. If the initial TIC > TAN, pH then increased steadily but slowly from 8 to 96 h. When the initial TIC < TAN, the pH declined or did not change after 20 h incubation. The initial pH elevation rate increased with temperature and initial concentration of TIC. Calculation indicated that the NH3 partial pressure (PNH3) in equilibrium with the slurry increased and pH decreased at increasing temperature if gases could not exchange between the slurry and the atmosphere. From the open slurry system PNH3 increased with temperature during the first 1–20 h. At 16 and 22 °C the PNH3 declined to low values after 20 h, whereas at 10 °C the PNH3 remained appreciable after 20 h. This explains why high accumulated NH3 losses may occur when slurry is applied to the field at low temperatures.

Type
Crops and Soils
Information
The Journal of Agricultural Science , Volume 127 , Issue 1 , August 1996 , pp. 109 - 116
Copyright
Copyright © Cambridge University Press 1996

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Asman, W. A. H. & van Jaarsveld, H. A. (1992). A variable-resolution transport model applied for NHx in Europe. Atmospheric Environment 26A, 445464.CrossRefGoogle Scholar
Beutier, D. & Renon, H. (1978). Representation of NH3-H2S-H2O, NH3-CO2-H2O and NH3-SO2-H2O vapor-liquid equilibria. Industrial Engineering Chemical Process Design Development 17, 220230.Google Scholar
Cooper, P & Cornforth, I. S. (1978). Volatile fatty acids in stored animal slurry. Journal of the Science of Food and Agriculture 29, 1927.CrossRefGoogle Scholar
Husted, S., Jensen, L. S. & Jorgensen, S. S. (1991). Reducing ammonia loss from cattle slurry by the use of acidifying additives: the role of the buffer system. Journal of the Science of Food and Agriculture 57, 335349.Google Scholar
Hutchings, N., Sommer, S. G. & Jarvis, S. (1996). A model of ammonia volatilization from a grazing livestock farm. Atmospheric Environment 30, 589599.CrossRefGoogle Scholar
Japenga, J & Harmsen, K. (1990). Determination of mass balances and ionic balances in animal manure. Netherlands Journal of Agricultural Science 38, 353367.Google Scholar
Jenkinson, D. S. (1990). An introduction to the global nitrogen cycle. Soil Use and Management 6, 5661.CrossRefGoogle Scholar
Kirchmann, H. & Lundvall, A. (1993). Relationship between N immobilization and volatile fatty acids in soil after application of pig and cattle slurry. Biology and Fertility of Soil 15, 161164.CrossRefGoogle Scholar
Muck, R. E. & Steenhuis, T. S. (1982). Nitrogen losses from manure storage. Agricultural Wastes 4, 4154.Google Scholar
Olesen, J. E. & Sommer, S. G. (1993). Modelling effects of wind speed and surface cover on ammonia volatilization from stored pig slurry. Atmospheric Environment 27A, 25672574.Google Scholar
Pain, B. F., Phillips, V. R., Clarkson, C. R. & Klarenbeek, J. V. (1989). Loss of nitrogen through ammonia volatilisation during and following the application of pig or cattle slurry to grassland. Journal of the Science of Food and Agriculture 47, 112.CrossRefGoogle Scholar
Paul, J. W. & Beauchamp, E. G. (1989). Relationship between volatile fatty acids, total ammonia, and pH in manure slurries. Biological Wastes 29, 313318.Google Scholar
Schulze, E.-D., De Vries, W., Hauhs, M., Rosén, K., Rasmussen, L., Tamm, C.-O. & Nilsson, J. (1989). Critical loads for nitrogen deposition on forest ecosystems. Water, Air and Soil Pollution 48, 451456.Google Scholar
Sherlock, R. R. & Goh, K. M. (1985). Dynamics of ammonia volatilization from simulated urine patches and aqueous urea applied to pasture. II. Theoretical derivation of a simplified model. Fertilizer Research 6, 322.CrossRefGoogle Scholar
Söderlund, R. & Svensson, B. H. (1976). The global nitrogen cycle. Ecological Bulletin 22, 2373.Google Scholar
Sommer, S. G. & Husted, S. (1995 a). The chemical buffer system in raw and digested animal slurry. Journal of Agricultural Science, Cambridge 124, 4553.Google Scholar
Sommer, S. G. & Husted, S. (1995 b). A simple model of pH in slurry. Journal of Agricultural Science, Cambridge 124, 447–453.Google Scholar
Sommer, S. G., Olesen, J. E. & Christensen, B. T. (1991). Effects of temperature, wind speed and air humidity on ammonia volatilization from surface applied cattle slurry. Journal of Agricultural Science, Cambridge 117, 91100.Google Scholar
van Der Molen, J., Beljaars, A. C. M., Chardon, W. J., Jury, W. A. & van Faassen, H. G. (1990). Ammonia volatilization from arable land after application of cattle slurry. 2. Derivation of a transfer model. Netherlands Journal of Agricultural Science 38, 239254.Google Scholar