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The nitrogen cycle in the Broadbalk Wheat Experiment: recovery and losses of 15N-labelled fertilizer applied in spring and inputs of nitrogen from the atmosphere

Published online by Cambridge University Press:  27 March 2009

D. S. Powlson
Affiliation:
Soils and Plant Nutrition Department, Rothamsted Experimental Station, Harpenden, Herts., AL5 2JQ
The Late G. Pruden
Affiliation:
Soils and Plant Nutrition Department, Rothamsted Experimental Station, Harpenden, Herts., AL5 2JQ
A. E. Johnston
Affiliation:
Soils and Plant Nutrition Department, Rothamsted Experimental Station, Harpenden, Herts., AL5 2JQ
D. S. Jenkinson
Affiliation:
Soils and Plant Nutrition Department, Rothamsted Experimental Station, Harpenden, Herts., AL5 2JQ

Summary

15N-labelled nitrogen fertilizer (containing equal quantities of ammonium-N and nitrate-N) was applied in 4 consecutive years (1980–3) to different microplots located within the Broadbalk Wheat Experiment at Rothamsted, an experiment which has carried winter wheat continuously since 1843. Plots receiving 48, 96, 144 and 192 kg N/ha every year were given labelled fertilizer in mid-April at (nominally) these rates.

Grain yields ranged from 1–2 t/ha on plots given no N fertilizer since 1843 to a maximum of 7·3 t/ha with 196 kg N/ha. On plots given adequate P and K fertilizer, between 51 and 68% of the labelled N was recovered in the above-ground crop; only about 40% was recovered where P deficiency limited crop growth. In 1981 fertilizerderived N retained in soil (0–70 cm) at harvest increased from 16 kg/ha, where 48 kg/ha was applied, to 38 kg/ha, where 192 kg/ha was applied. More than 80% of this retained N was in the plough layer (0–23 cm).

Overall recovery of fertilizer N in crop plus soil ranged from 70 % to more than 90 % over the 4 years of the experiments. Losses of N were larger in years when spring rainfall was above average and when soil moisture deficits shortly after application were small.

Crop uptake of unlabelled N derived from soil increased from 28 kg N/ha on the plot given no fertilizer N to 67 kg N/ha on the plot given 144 kg N/ha. The extra uptake of unlabelled N was mainly, if not entirely, due to greater mineralization of soil N in the plots that had been given N fertilizer for many years. Presumably fertilizer N increased the annual return of crop residues, which in turn led to an accumulation of mineralizable organic N, although there was only a small increase in total soil N content.

Wheat given NH4-N grew less well and took up less N than wheat given N08-N in the relatively dry spring of 1980; there was little difference between the two forms of N in the wetter spring of 1981. In both years more fertilizer N was retained in the soil at harvest when fertilizer was applied as NH4-N than as N03-N.

The N content of the soil in several plots of the experiment has been constant for many years, so that the annual removal of N is balanced by the annual input. A nitrogen balance for the plot given 144 kg fertilizer N/ha showed an average annual input of non-fertilizer N of at least 48 kg/ha, of which N in rain and seed accounts for about 14 kg/ha. The remainder may come from biological fixation of atmospheric N2 by blue-green algae, or from dry deposition of oxides of nitrogen and/or NH3 onto crop and soil. The overall annual loss of N from the crop–soil system on this particular plot was 54 kg N/ha per year, 28% of the total annual input from fertilizer and nonfertilizer N.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1986

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References

REFERENCES

Addiscott, T. M. (1977). A simple computer model for leaching in structured soils. Journal of Soil Science 28, 554563.CrossRefGoogle Scholar
Avery, B. W. & Bullock, P. (1969). The soils of Broadbalk. Morphology and classification of Broad balk soils. Rothamsted Experimental Station Report for 1968, Part 2, pp. 6381.Google Scholar
Barbaclough, P. B. & Leigh, R. A. (1984). The growth and activity of winter wheat roots in the field: the effect of sowing date and soil type on root growth of high-yielding crops. Journal of Agricultural Science, Cambridge 103, 5974.CrossRefGoogle Scholar
Barrett, C. F. (1983). Acid Deposition in the United Kingdom. Warren Spring Laboratory, Stevenage, 72 pp.Google Scholar
Bremner, J. M. (1965 a). Total nitrogen. In Methods of Soil Analysis. Part 2 (ed. Black, C. A.), pp. 11491178. Madison: American Society of Agronomy.Google Scholar
Bremner, J. M. (1965 b). Inorganic forms of nitrogen. In Methods of Soil Analysis. Part 2 (ed. Black, C. A.), pp. 11791237. Madison: American Society of Agronomy.Google Scholar
Brimblecombe, P. & Pitman, J. (1980). Long-term deposit at Rothamsted, southern England. Tellus 32, 261267.CrossRefGoogle Scholar
Dowdell, R. J. & Crees, R. (1980). The uptake of 15N-Iabelled fertilizer by winter wheat and its immobilization in a clay soil after direct drilling or ploughing. Journal of the Science of Food and Agriculture 31, 992996.CrossRefGoogle Scholar
Dowdell, R. J., Webster, C. P., Hill, D. & Mercer, E. R. (1984). A lysimeter study of the fate of fertilizer nitrogen in spring barley crops grown on a shallow soil overlying chalk: crop uptake and leaching losses. Journal of Soil Science 35, 169181.CrossRefGoogle Scholar
Dyke, G. V., George, B. J., Johnston, A. E., Poulton, P. R. & Todd, A. D. (1983). The Broadbalk Wheat Experiment 1968–78: yields and plant nutrients in crops grown continuously and in rotation. Rothamsted Experimental Station Report for 1982, Part 2, pp. 544.Google Scholar
Farquhar, G. D., Wetselaar, R. & Weir, R. (1983). Gaseous nitrogen losses from plants. In Gaseous Loss of Nitrogen from Plant-Soil Systems (ed. Freney, J. R. and Simpson, J. R.), pp. 159180. The Hague: Martin us Nijhoff.CrossRefGoogle Scholar
Fowler, D. (1978). Wet and dry deposition of sulphur and nitrogen compounds from the atmosphere. In Effects of Acid Precipitation on Terrestrial Ecosystems (ed. Hutchinson, T. C. and Havas, M.), pp. 927. New York: Plenum Press.Google Scholar
Galbally, I. E. & Roy, C. R. (1983). The fate of nitrogen compounds in the atmosphere. In Gaseous Loss of Nitrogen from Plant-Soil Systems (ed. Freney, J. R. and Simpson, J. R.), pp. 265284. The Hague: Martinus Nijhoff.CrossRefGoogle Scholar
Gregory, P. J., Crawford, D. V. & Mcgowan, M. (1979). Nutrient relations of winter wheat. 1. Accumulation and distribution of Na, K, Ca, Mg, P, S and N. Journal of Agricultural Science, Cambridge 93, 485494.CrossRefGoogle Scholar
Hart, P. B. S., Jenkinson, D. S., Johnston, A. E., Powlson, D. S. & Pruden, G. (1982). The uptake by wheat of fertilizer N applied to the preceding crop. Rothamsted Experimental Station Report for 1981, Part 1, p. 254.Google Scholar
Jansson, S. L. (1958). Tracer studies on nitrogen transformations in soil with special attention to mineralization and immobilization relationships. Annals of the Royal Agricultural College of Sweden 24, 101361.Google Scholar
Jenkinson, D. S. (1977). The nitrogen economy of the Broadbalk experiments. I. Nitrogen balance in the experiments. Rothamsted Experimental Station Report for 1976, Part 2, pp. 103109.Google Scholar
Jenkinson, D. S. (1982). The nitrogen cycle in long term field experiments. Philosophical Transactions of the Royal Society, London, B, 296, 563571.Google Scholar
Jenkinson, D. S., Fox, R. L. & Rayner, J. H. (1985). Interactions between fertilizer nitrogen and soil nitrogen – the so-called priming effect. Journal of Soil Science 36, 425444.CrossRefGoogle Scholar
Johnston, A. E. (1969). Plant nutrients in Broadbalk soils. Rothamsted Experimental Station Report for 1968, Part 2, pp. 93115.Google Scholar
Johnston, A. E. & Garner, H. V. (1969). Broadbalk: historical introduction. Rothamsted Experimental Station Report for 1968, Part 2, pp. 1225.Google Scholar
Khanip, Y. M., Van Cleemput, O. & Baert, L. (1984). Field study of the fate of labelled fertilizer nitrate applied to barley and maize in sandy soils. Fertilizer Research 5, 289294.CrossRefGoogle Scholar
Kjellerup, V. & Dam Kofoed, A. (1983). Nitrogen fertilization in relation to leaching of plant nutrients from soil. Lysimeter experiments with 15N. Tidsskrift for Planteavl 87, 122.Google Scholar
Leitch, M. H. & Vaidyanathan, L. V. (1983). N use by winter wheat established in cultivated and direct drilled soils. Journal of Agricultural Science, Cambridge 100, 461471.CrossRefGoogle Scholar
Olson, R. V., Murphy, L. S., Moser, H. C. & Swallow, C. W. (1979). Fate of tagged fertilizer nitrogen applied to winter wheat. Soil Science Society of America Journal 43, 973975.CrossRefGoogle Scholar
Powlson, D. S., Hart, P. B. S., Pruden, G. & Jenkinson, D. S. (1986). Recovery of 15 N-labelled fertilizer applied in autumn to winter wheat at four sites in eastern England. Journal of Agricultural Science, Cambridge 107, 611620.CrossRefGoogle Scholar
Prew, R. D., Church, B. M., Dewar, A. M., Lacey, J., Penny, A., Plumb, R. T., Thorne, G. N., Todd, A. D. & Williams, T. D. (1983). Effects of eight factors on the growth and nutrient uptake of winter wheat and on the incidence of pests and diseases. Journal of Agricultural Science, Cambridge 100, 363382.CrossRefGoogle Scholar
Pruden, G., Powlson, D. S. & Jenkinson, D. S. (1985). The measurement of 15N in soil and plant material. Fertilizer Research 6, 205218.CrossRefGoogle Scholar
Rodgers, G. A. (1978). Dry deposition of atmospheric ammonia at Rothamsted in 1976 and 1977. Journal of Agricultural Science, Cambridge 90, 537542.CrossRefGoogle Scholar
Rothamsted Experimental Station (19801983). Broad-balk. In Yields of the Field Experiments, Rothamsted, 80/R/BK/l to 83/R/BK/l.Google Scholar
Smith, K. A., Elmes, A. E., Howard, R. S. & Franklin, M. F. (1984). The uptake of soil and fertilizer-nitrogen by barley growing under Scottish climatic conditions. Plant and Soil 76, 4957.CrossRefGoogle Scholar
Tjepkema, J. D., Cartica, R. J. & Hemond, H. F. (1981). Atmospheric concentration of ammonia in Massachusetts and deposition on vegetation. Nature, London 294, 446–446.CrossRefGoogle Scholar
Van Cleemput, O. & Baert, L. (1984). The fate of labelled fertilizer nitrogen, split applied to winter wheat on a clay soil. Pedologie 34, 291300.Google Scholar
Widdowson, F. V., Darby, R. J. & Bird, E. (1982). Nitrogen in soils under winter wheat during winter and spring. Rothamsted Experimental Station Report for 1981, pp. 250251.Google Scholar
Witty, J. F., Keay, P. J., Frogatt, P. J. & Dart, P. J. (1979). Algal nitrogen fixation on temperate arable fields. The Broadbalk Experiment. Plant and Soil 52, 151164.CrossRefGoogle Scholar
Woodcock, T. M., Pruden, G., Powlson, D. S. & Jenkinson, D. S. (1982). Apparatus for applying 15N labelled fertilizer uniformly to field micro-plots. Journal of Agricultural Engineering Research 27, 369372.CrossRefGoogle Scholar