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A winter wheat crop simulation model without water or nutrient limitations

Published online by Cambridge University Press:  27 March 2009

A. H. Weir
Affiliation:
Bothamsted Experimental Station, Harpenden, Herts., AL5 2JQ
P. L. Bragg
Affiliation:
Agricultural Research Council Letcombe Laboratory, Wantage, Oxfordshire, OX12 9JT
J. R. Porter
Affiliation:
Long Ashton Research Station, University of Bristol, Long Ashton, Bristol, BS18 9AF
J. H. Rayner
Affiliation:
Bothamsted Experimental Station, Harpenden, Herts., AL5 2JQ

Summary

A whole crop computer simulation model of winter wheat has been written in FORTRAN and used to simulate the growth of September- and October-sown crops of Hustler wheat at Rothamsted for the years 1978–9, 1979–80 and 1980–1. Results of the simulations, which are for crops with adequate water and nutrients, are compared with observations from experiments at Rothamsted. The model uses daily maximum and minimum temperatures and daylength to calculate the dates of emergence, double ridge, anthesis and maturity of the crops and the growth and senescence of tillers and leaves. In the simulations, the canopy intercepts daily radiation and produces dry matter that is partitioned between roots, shoots, leaves, ears and grain. Partial simulations, using observed LAI values, produced dry matter in close agreement with observations of late-sown crops, but consistently overestimated the total dry-matter production of the early-sown crops. Full simulation described satisfactorily the average difference in dry-matter production to be expected with changes in time of sowing, but did not give as close correspondence for individual crops. A grain growth submodel, that linked maximum grain weight to average temperatures during the grain growth period, correctly simulated the observed growth of individual grains in the 1981 crop. The benefits to be obtained by combining whole crop modelling with detailed crop observations are discussed.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1984

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References

Arndt, C. H. (1945). Temperature-growth relationships of the roots and hypocotyls of cotton seedlings. Plant Physiology 20, 200220.CrossRefGoogle Scholar
Austin, R. B., Edrich, J. A., Ford, M. A. & Blackwell, R. D. (1977). The fate of the dry matter, carbohydrates and 14C lost from the leaves and stems of wheat during grain filling. Annals of Botany 41, 13091327.CrossRefGoogle Scholar
Charles-Edwards, D. A. (1978). An analysis of the photosynthesis and productivity of vegetable crops in the United Kingdom. Annals of Botany 42, 717731.CrossRefGoogle Scholar
De Wit, C. T., Goudriaan, J., Van Laar, H. H., Penning de Vries, F. W. T., Rabbinge, R. R., Van Keulen, H., Louwerse, W., Simba, L. & de Jonge, C. (1978). Simulation of assimilation, respiration and transpiration of crops. Pudoc, Wageningen, The Netherlands.Google Scholar
Francis, C. A. (1970). Effective day-lengths for the study of photo-period sensitive reactions in plants. Agronomy Journal 62, 790792.CrossRefGoogle Scholar
Gallagher, J. N., Thorne, G. N. & Taylor, P. J. (1981). Development of winter wheat. Rothamsted Experimental Station, Report for 1980. Part 1, pp. 5354.Google Scholar
Hochman, Z. (1979). Wheat in a semi-arid environment: a field and simulation study of the effects of water stress on yield. M.Sc. thesis, University of Sydney.Google Scholar
Landsberq, J. J. & Porter, J. R. (1982). The ARC Wheat Model. In Aspects of Crop Growth Agronomy Conference (ed. Davies, J. E. and Shotton, F. E.). MAFF Reference Book 341, pp. 104115. London: H.M.S.O.Google Scholar
Lumsden, M. E. (1980). The influence of weather on the development of winter wheat. B.Sc. thesis, University of Bath.Google Scholar
McCree, K. J. (1974). Equation for the rate of dark respiration of white clover and grain sorghum, as functions of dry weight, photosynthetic rate, and temperature. Crop Science 14, 509514.CrossRefGoogle Scholar
Marshall, B. & Biscoe, P. V. (1980 a). A model for C3 leaves describing the dependence of net photosynthesis on irradiance. I. Derivation. Journal of Experimental Botany 31, 2939.CrossRefGoogle Scholar
Marshall, B. & Biscoe, P. V. (1980 b). A model for C3 leaves describing the dependence of net photosynthesis on irradiance. II. Application to the analysis of flag leaf photosynthesis. Journal of Experimental Botany 31, 4148.CrossRefGoogle Scholar
Martinez-Carrasco, R. & Thorne, G. N. (1979). Effects of crop thinning and reduced grain numbers per ear on grain size in two winter wheat varieties given different amounts of nitrogen. Annals of Applied Biology 92, 383393.CrossRefGoogle Scholar
Milthorpe, F. L. & Moorby, J. (1979). An Introduction to Crop Physiology. Cambridge: Cambridge University Press.Google Scholar
Morgan, J. M. (1976). Asimulation model of the growth of the wheat plant. Ph.D. thesis, Macquarie University.Google Scholar
Pearman, I., Thomas, S. M. & Thorne, G. N. (1977). Effects of nitrogen fertilizer on growth and yield of spring wheat. Annals of Botany 41, 93108.CrossRefGoogle Scholar
Penning de Vries, F. W. T. & Van Laar, H. H. (ed.) (1982). Simulation of Plant Growth and Crop Production. Pudoc, Wageningen, The Netherlands.Google Scholar
Porter, J. R. (1984). A model of canopy development in winter wheat. Journal of Agricultural Science, Cambridge 102, 383392.CrossRefGoogle Scholar
Porter, J. R., Bragg, P. L., Rayner, J. H., Weir, A. H. & Landsberg, J. J. (1983). The ARC wheat simulation model – principles and progress. In Opportunities for Manipulations of Cereal Productivity (ed. Hawkins, A. and Jeffcoat, B.). British Plant Growth Regulator Group, Monograph 7, pp. 97108.Google 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
Spiertz, J. H. J. (1977). The influence of temperature and light intensity on grain growth in relation to the carbohydrate and nitrogen economy of the wheat plant. Netherlands Journal of Agricultural Science 25, 182197.CrossRefGoogle Scholar
Tenhunen, J. D., Weber, J. A., Yocum, C. S. & Gates, D. M. (1976). Development of a photosynthesis model with an emphasis on ecological applications. II. Analysis of a data set describing the PM surface. Oecologia 26, 101119.CrossRefGoogle Scholar
Tenhunen, J. D., Yocum, C. S. & Gates, D. M. (1976). Development of a photosynthesis model with an emphasis on ecological applications. I. Theory. Oecologia 26, 89100.CrossRefGoogle ScholarPubMed
Thorne, G. N., Dewar, A. M., Williams, T. D., Lacey, J., Plumb, R. T., Prew, R. D., Church, B. M. & Todd, A. D. (1982). Factors limiting yield of winter wheat. Rothamsted Experimental Station, Report for 1980, Part 1, pp. 1920.Google Scholar
Thorne, G. N., Dewar, A. M., Williams, T. D., Lacey, J., Plumb, R. T., Prew, R. D., Penny, A., Church, B. M. & Todd, A. D. (1981). Factors limiting yield winter wheat. Rothamsted Experimental Station, Report for 1981, Part 1, p. 18.Google Scholar
Thornley, J. H. M. (1976). Mathematical Models in Plant Physiology. London and New York: Academic Press.Google Scholar