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Rapid reduction of nitrate in soil re-moistened after air-drying

Published online by Cambridge University Press:  27 March 2009

P. A. Cawse
Affiliation:
Health Physics and Medical Division, Atomic Energy Research Establishment, Harwell, Berkshire
D. Sheldon
Affiliation:
Health Physics and Medical Division, Atomic Energy Research Establishment, Harwell, Berkshire

Summary

When an organic calcareous soil was air-dried for 2 days and re-wetted to a wide range of moisture contents, well below saturation, nitrite accumulated within 1–2 days. At the same time much nitrate was formed and more carbon dioxide was released than from soil kept moist. On further incubation of re-wetted soil for 3–5 days, the nitrite concentration decreased rapidly. Since 15N-labelled nitrate was reduced to nitrite after air-drying and re-wetting, and no nitrite was formed in autoclaved soil, nitrate was microbially reduced.

Eighty-three per cent of added 15N tracer was recovered from the soil 2 days after re-wetting to 70 % moisture, indicating that 58 ppm N had been lost; 10 ppm N of this was released as nitrous oxide. Autoclaved soil to which nitrite was added did not evolve nitrous oxide, suggesting that nitrite was reduced biologically rather than decomposed chemically.

Three other soils were treated similarly; two, which were non-calcareous, accumulated no nitrite. Fresh calcareous soils with high respiration rates and good capacities to denitrify when waterlogged are most likely to form nitrite after drying and moderate re-wetting.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1972

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References

REFERENCES

Allison, L. E. (1960). Wet-combustion apparatus and procedure for organic and inorganic carbon in soil. Proc. Soil Sci. Soc. Am. 24, 3640.CrossRefGoogle Scholar
Birch, H. F. (1958). The effect of soil drying on humus decomposition and nitrogen availability. Pl. Soil 10, 931.CrossRefGoogle Scholar
Bremner, J. M. (1965). Total nitrogen. In Methods of Soil Analysis (ed. Black, C. A.), pp. 1149–78. Madison, Wisconsin: American Society of Agronomy.Google Scholar
Bremner, J. M. & Fuhr, F. (1966). Tracer studies of the reactions of soil organic matter with nitrite. In Use of Isotopes in Soil Organic Matter Studies, pp. 337–46. Oxford: Pergamon Press.Google Scholar
Bremner, J. M. & Jenkinson, D. S. (1960). Determination of organic carbon in soil. J. Soil Sci. 11, 394402.CrossRefGoogle Scholar
Bremner, J. M. & Shaw, K. (1958). Denitrification in soil. J. agric. Sci., Oamb., 51, 2252.CrossRefGoogle Scholar
Broadbent, F. E. (1951). Denitrification in some California soils. Soil Sci. 72, 129–37.CrossRefGoogle Scholar
Broadbent, F. E. & Stojanovic, B. F. (1952). The effect of partial pressure of oxygen on some soil nitrogen transformations. Proc. Soil Sci. Soc. Am. 16, 359–63.CrossRefGoogle Scholar
Campbell, N. E. R. & Lees, H. (1967). The nitrogen cycle. In Soil Biochemistry, vol. I (ed. McLaren, A. D. and Peterson, G. H.), pp. 194215. New York: Marcel Dekker, Inc.Google Scholar
Cawse, P. A. & Cornfield, A. H. (1969). The reduction of 15N-labelled nitrate to nitrite by fresh soils following treatment with gamma radiation. Soil Biol. Biochem. 1, 267–74.CrossRefGoogle Scholar
Cawse, P. A. & Cornfield, A. H. (1971). Factors affecting the formation of nitrite in γ-irradiated soils and its relationship with denitrifying potential. Soil Biol. Biochem. 3, 111–20.CrossRefGoogle Scholar
Cooper, G. S. & Smith, R. L. (1963). Sequence of products formed during denitrification in some diverse Western soils. Proc. Soil Sci. Soc. Am. 27, 659–62.CrossRefGoogle Scholar
Crosby, N. T. (1967). The determination of nitrite in water using Cleve's acid, l-naphthylamine-7-sulphonic acid. Proc. Soc. Wat. Treat. Exam. 10, 51–5.Google Scholar
Ekpete, D. M. & Cornfield, A. H. (1964). Losses, through denitrification, from soil of applied inorganic nitrogen even at low moisture contents. Nature, Lond. 201, 322–3.CrossRefGoogle Scholar
Ekpete, D. M. & Cornfield, A. H. (1965a). Effect of varying static and changing moisture levels during incubation on the mineralization of carbon in soil. J. agric. Sci., Camb. 64, 205–9.CrossRefGoogle Scholar
Ekpete, D. M. & Cornfield, A. H. (1965b). Effect of pH and addition of organic materials on denitrification losses from soil. Nature, Land. 208, 1200.CrossRefGoogle Scholar
Gasser, J. K. R. (1958). Use of deep freezing in the preservation and preparation of fresh soil samples. Nature, Lond. 181, 1334–5.CrossRefGoogle Scholar
Greenwood, D. J. (1968). Measurement of microbial metabolism in soil. In The Ecology of Soil Bacteria (ed. Gray, T. R. G. and Parkinson, D.), pp. 138–57. Liverpool: University Press.Google Scholar
Harpstead, M. I. & Brage, B. L. (1958). Storage of soil samples and its effect upon the subsequent accumulation of nitrate nitrogen during controlled incubation. Proc. Soil Sci. Soc. Am. 22, 326–8.CrossRefGoogle Scholar
Jager, G. (1968). The influence of drying and freezing of soil on its organic matter decomposition. Stikslof no. 12, 7588.Google Scholar
Jenkinson, D. S. (1966). Studies on the decomposition of plant material in soil. II. Partial sterilisation of soil and the soil biomass. J. Soil Sci. 17, 280302.CrossRefGoogle Scholar
Kay, F. F. (1934). A soil survey of the eastern portion of the Vale of the White Horse. Bulletin no. 48, University of Reading.Google Scholar
Kay, F. F. (1936). A soil survey of the University farm, Sonning, Berks. Bulletin no. 49, University of Reading.Google Scholar
Keeney, D. R. & Bremner, J. M. (1966). Comparison and evaluation of laboratory methods of obtaining an index of soil nitrogen availability. Agron. J. 58, 498503.CrossRefGoogle Scholar
McGarity, J. W. (1962). Effect of freezing of soil on denitrification. Nature, Lond. 196, 1342–3.CrossRefGoogle Scholar
McGarity, J. W. & Hauce, R. D. (1969). An aerometric apparatus for the evaluation of gaseous nitrogen transformations in field soils. Soil Sci. 108, 335–44.CrossRefGoogle Scholar
Nommik, H. (1956). Investigations on denitrification in soil. Acta Agric. scand. 6, 195228.CrossRefGoogle Scholar
Patrick, W. H. Jn & Wyatt, R. (1964). Soil nitrogen loss as a result of alternate submergence and drying. Proc. Soil Sci. Soc. Am. 28, 647–53.CrossRefGoogle Scholar
Soulides, D. A. & Allison, F. E. (1961). Effect of drying and freezing soils on carbon dioxide production, available mineral nutrients, aggregation, and bacterial population. Soil Sci. 91, 291–8.CrossRefGoogle Scholar
Stevenson, I. L. (1956). Some observations on the microbial activity in remoistened air-dried soils. Pl. Soil 8, 170–82.CrossRefGoogle Scholar
Valera, C. L. & Alexander, M. (1961). Nutrition and physiology of denitrifying bacteria. Pl. Soil 15, 268–80.CrossRefGoogle Scholar
Wullstein, L. H. (1967). Soil nitrogen volatilisation. Agric. Sci. Rev. 5, 813.Google Scholar