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Computer simulation of changes in soil mineral nitrogen and crop nitrogen during autumn, winter and spring

Published online by Cambridge University Press:  27 March 2009

T. M. Addiscott  and
A. P. Whitmore
T. M. Addiscott
Affiliation:
Rothamsted Experimental Station, Harpenden, Herts
A. P. Whitmore
Affiliation:
Rothamsted Experimental Station, Harpenden, Herts
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Summary

The computer model described simulates changes in soil mineral nitrogen and crop uptake of nitrogen by computing on a daily basis the amounts of N leached, mineralized, nitrified and taken up by the crop. Denitrification is not included at present. The leaching submodel divides the soil into layers, each of which contains mobile and immobile water. It needs points from the soil moisture characteristic, measured directly or derived from soil survey data; it also needs daily rainfall and evaporation. The mineralization and nitrification submodel assumes pseudo-zero order kinetics and depends on the net mineralization rate in the topsoil and the daily soil temperature and moisture content, the latter being computed in the leaching submodel. The crop N uptake and dry-matter production submodel is a simple function driven by degree days of soil temperature and needs in addition only the sowing date and the date the soil returns to field capacity, the latter again being computed in the leaching submodel. A sensitivity analysis was made, showing the effects of 30% changes in the input variables on the simulated amounts of soil mineral N and crop N present in spring when decisions on N fertilizer rates have to be made. Soil mineral N was influenced most by changes in rainfall, soil water content, mineralization rate and soil temperature, whilst crop N was affected most by changes in soil temperature, rainfall and sowing date. The model has so far been applied only to winter wheat growing through autumn, winter and spring but it should be adaptable to other crops and to a full season.

The model was validated by comparing its simulations with measurements of soil mineral N, dry matter and the amounts of N taken up by winter wheat in experiments made at seven sites during 5 years. The simulations were assessed graphically and with the aid of several statistical summaries of the goodness of fit. The agreement was generally very good; over all years 72% of all simulations of soil mineral N to 90 cm depth were within 20 kg N/ha of the soil measurements; also 78% of the simulations of crop nitrogen uptake were within 15 kg N/ha and 63% of the simulated yields of dry matter were within 25 g/m2 of the amounts measured. All correlation coefficients were large, positive, and highly significant, and on average no statistically significant differences were found between simulation and measurement either for soil mineral N or for crop N uptake.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 109 , Issue 1 , August 1987 , pp. 141 - 157
Copyright
Copyright © Cambridge University Press 1987

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References

Addiscott, T. M. (1977). A simple computer model for leaching in structured soils. Journal of Soil Science 28, 554563.CrossRefGoogle Scholar
Addiscott, T. M. (1982). Computer assessment of the N status during winter and early spring of soils growing winter wheat. In Assessment of the Nitrogen Status of the Soils(ed. Batey, T., Vlassak, K. and Verstraeten, L. M. J.), pp. 1526. Leuven: Katholieke Universiteit Leuven.Google Scholar
Addiscott, T. M. (1983 a). Computer assessment of soil N in spring.Can it improve N efficiency ? Journal of the Science of Food and Agriculture 34, 710711.Google Scholar
Addiscott, T. M. (1983 b). Kinetics and temperature relationships of mineralization and nitrification in Rothamsted soils with differing histories. Journal of Soil Science 34, 343353.CrossRefGoogle Scholar
Addiscott, T. M., Rose, D. A. & Bolton, J. (1978). Chloride leaching in the Rothamsted drain gauges: influence of rainfall pattern and soil structure. Journal of Soil Science 29, 305314.CrossRefGoogle Scholar
Addiscott, T. M., Thomas, V. H. & Janjua, M. A. (1983). Measurement and simulation of anion diffusion in natural soil aggregates and clods. Journal of Soil Science 34, 709721.CrossRefGoogle Scholar
Addiscott, T. M. & Whitmoke, A. P. (1986). Putting nitrogen predictions on the screen. Soil and Water 14, 1719.Google Scholar
Barraclouoh, 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
Clarkson, D. T. & Warner, A. (1979). Relationships between root temperature and the transport of ammonium and nitrate ions by Italian and perennial ryegrass (Lolium multiflorumand Lolium perenne). Plant Physiology 64, 557561.CrossRefGoogle ScholarPubMed
Cooke, G. W. (1979). Some priorities for British soil science. Journal of Soil Science 30, 187213.CrossRefGoogle Scholar
Crossett, R. N., Campbell, D. J. & Stewart, H. E. (1975). Compensatory growth in cereal root systems. Plant and Soil 42, 673683.CrossRefGoogle Scholar
Darby, R. J., Widdowson, F. V., Bird, E. & Hewitt, M. V. (1986). The relationship of soil mineral NO3-N with stem NO3-N concentration and of fertilizer-N with the amount of nitrogen taken up by winter wheat, in experiments testing nitrogen fertilizer in combination with aphicide and fungicides, from 1980 to 1982. Journal of Agricultural Science, Cambridge 106, 497507.CrossRefGoogle Scholar
Darby, R. J., Widdowson, F. V. & Hewitt, M. V. (1984). Comparisons between the establishment, growth and yield of winter wheat on three clay soils, in experiments testing nitrogen fertilizer in combination with aphicide and fungicides, from 1980 to 1982. Journal of Agricultural Science, Cambridge 103, 595611.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 shallow soil overlying Chalk: crop uptake and leaching losses. Journal of Soil Science 35, 169181.CrossRefGoogle Scholar
Drew, M. C. & Saker, L. R. (1975). Nutrient supply and the growth of the seminal root system in barley. II. Localised compensatory increases in lateral root growth and nitrate uptake. Journal of Experimental Botany 26, 7990.CrossRefGoogle Scholar
Gerwitz, A. & Page, E. R. (1974). An empirical mathematical model to describe plant root systems. Journal of Applied Ecology 11, 773781.CrossRefGoogle Scholar
Greenwood, D. J. (1982). Modelling of crop response to nitrogen fertilizer. Philosophical Transactions of the Royal Society, London B296, 351362.Google Scholar
Greenwood, D. J. (1986). Prediction of nitrogen fertiliser needs of arable crops. In Advances in Plant Nutrition, vol. II (ed. Tinker, P. B. and Laüchli, A.), pp. 161. New York: Praeger.Google Scholar
Greenwood, D. J., Cleaver, T. J., Loquens, S. H. M. & Niensorf, K. B. (1977). Relationship between plant weight and growing period for vegetable crops in the United Kingdom. Annals of Botany 41, 977987.CrossRefGoogle Scholar
Greenwood, D. J., Neeteson, J. J. & Draycott, A. (1985). Response of potatoes to N fertilizer: dynamic model. Plant and Soil 85, 185203.CrossRefGoogle Scholar
Gregory, P. J., McGowan, M., Biscoe, P. V. & Hunter, B.(1978). Water relations of winter wheat. I. Growth of the root system. Journal of Agricultural Science, Cambridge 91, 91102.CrossRefGoogle Scholar
Hall, D. G. M., Reeve, M. J., Thomasson, A. J. & Wright, V. F. (1977). Water Retention, Porosity and Density of Field Soils.Soil Survey Technical Monograph No. 9, 75.Google Scholar
Jenkinson, D. S. (1984). The supply of nitrogen from the soil. In The Nitrogen Requirement of Cereals. MAFF/ADAS Reference Book No. 385, pp. 7992. London: H.M.S.O.Google Scholar
Jenkinson, D. S., Powlson, D. S., Gregory, M. R., Hart, P. B. S., Johnston, A. E., MacDonald, A. J. & Pruden, G. (1984). Loss of spring-applied N. Report of the Rothamsted Experimental Station for 1983, Part 1, p. 173.Google Scholar
Ministry Or Agriculture, Fisheries And Food (1976). The agricultural climate of England and Wales. Technical Bulletin 35, pp. 2325. London: H.M.S.O.Google Scholar
Olsen, R. A., Frank, K. D., Diebert, E. J., Dreir, A. F., Sander, D. H. & Johnson, V. A. (1976). Impact of residual mineral N in soil on grain protein yields of winter wheat and corn. Agronomy Journal 68, 769772.CrossRefGoogle Scholar
Penman, H. L. & Schofield, R. K. (1941). Drainage and evaporation from fallow soil at Rothamsted. Journal of Agricultural Science, Cambridge 31, 74109.CrossRefGoogle Scholar
Powlson, D. S., Jenkinson, D. S., Pruden, G. & Johnston, A. E. (1983). Losses of [16N]-labelled fertilizer N applied to winter wheat. Report of the Rothamsted Experimental Station for 1982, Part 1, p. 263.Google Scholar
Prew, R. D., Beane, J., Carter, N., Church, B. M., Dewar, A. M., Lacey, J., Penny, A., Plumb, R. T., Thorne, G. N. & Todd, A. D. (1986). Some factors affecting the growth and yield of winter wheat grown as a third cereal with much or negligible take-all. Journal of Agricultural Science, Cambridge 107, 639671.CrossRefGoogle Scholar
Prew, R. D., Church, B. M., Dewar, A. M., Lacey, J., Magan, N., Penny, A., Plumb, R. T., Thorne, G. N., Todd, A. D. & Williams, T. D. (1985). Some factors limiting the growth and yield of winter wheat and their variation in two seasons. Journal of Agricultural Science, Cambridge 104, 135162.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
Remy, J.-G. & Herbert, J. (1977). Le devenir des engrais azotes dans le sol. Comptes Rendus de L' Académie Agricole de France 63, 700714.Google Scholar
Richter, J., Nordmeyer, H. & Kersebaum, Chr. K. (1985). Simulation of nitrogen regime in loess soils in the winter half-year: comparison between field measurements and simulations. Plant and Soil 83, 419431.CrossRefGoogle Scholar
Scharpf, H.-C. & Wehrmann, J. (1975). Die Bedeutung der Mineralstickstoffvorrates des Bodens für die Bemessung der N-Düngung zu Winterweizen. Landwirtschaftliche Forschung 32, 100114.Google Scholar
Stanford, G. & Epstein, E. (1974). Nitrogen mineralization - water relationships in soils. Soil Science Society of America Proceedings 38, 103107.CrossRefGoogle Scholar
Tabatabai, M. A. & Al-Khafaji, A. A. (1980). Comparison of nitrogen and sulphur mineralization in soils. Soil Science Society of America Journal 44, 10001006.CrossRefGoogle Scholar
Thompson, N., Barrie, I. A. & Aylet, M. (1981). Meteorological Office Rainfall and Evaporation Calculation System: MORECS. Hydrological Memorandum, no. 45. Bracknell: Meteorological Office.Google Scholar
Tinker, P. B. (1983). Nutrient and micronutrient requirement of cereals. In The Yield of Cereals. Proceedings of an International Seminar, held at Cambridge and Stoneleigh 29 07 -5 07 1983 (ed. Wright, D. W.) pp. 5967. Royal Agricultural Society of England, Monograph Series No. 1, London.Google Scholar
Tinker, P. B. & Widdowson, F. V. (1982). Maximising wheat yields, and some causes of yield variation. Proceedings of the Fertilizer Society 211, 149184.Google Scholar
Webster, C. P., & Dowdell, R. J. (1982). Nitrous oxide emission from permanent grass swards. Journal of the Science of Food and Agriculture 33, 227230.CrossRefGoogle Scholar
Whitmore, A. P. & Addiscott, T. M. (1986). Computer simulation of winter leaching losses of nitrate from soil Simulating nitrogen in soil and crop157 cropped with winter wheat. Soil Use and Management 2, 2630.CrossRefGoogle Scholar
whitmore, A. P. & Addiscott, T. M. (1987). A function for describing N uptake, dry matter production and rooting by wheat crops. Plant and Soil 101, 5160.CrossRefGoogle Scholar
Whitmore, A. P., Mandeville, P. J. & Davis, C. (1985). Mineralization rates. Report of the Rothamsted Experimental Station for 1984. Part 1, p. 182.Google Scholar
Whitmore, A. P., Milford, G. F. J. & Armstrong, M. J. (1987). Evaluation of a nitrogen leaching/mineralization model for sugar beet. Plant and Soil 101, 6165.CrossRefGoogle Scholar
Widdowson, F. V., Darby, R. J. & Bird, E. (1982). The prediction of nitrogen fertilizer rates from mineral N in the soil in spring. Report of the Rothamsted Experimental Station for 1981. Part 1, p. 251.Google Scholar
Widdowson, F. V., Penny, A., Darby, R. J., Bird, E. & Hewitt, M. V. (1987). Amounts of NO3-N and NH4-N in soil, from autumn to spring, under winter wheat and their relationship to soil type, sowing date, previous crop and N uptake at Rothamsted, Woburn and Saxmundham, 1979–85. Journal of Agricultural Science, Cambridge 108, 7395.CrossRefGoogle Scholar
Willigen, P. De & Neeteson, J. J. (1985). Comparison of six simulation models for the nitrogen cycle in the soil. Fertilizer Research 8, 157171.CrossRefGoogle Scholar