Abstract
Crop models are useful tools for assessing the impact of climate change on crop production. The dynamic crop-growth model, CERES-Wheat is used to examine crop management responses, including yield, under six climate change scenarios for the years 2025 and 2050 on the Estate of Imperial College at Wye, Kent, U.K. Sensitivity analysis shows a dry matter yield decrease in response to increases in temperature alone. CERES-Wheat was then constrained to assess the crop performance under water-limited production scenarios with different soils, and the results show that crop grain yield actually increases, largely due to CO2 fertilisation leading to increased rates of photosynthesis. Different management practices (planting dates and nitrogen application) were applied to find the best adaptation strategies. In general, `early' sowing (10th September) had the highest simulated yield, and `late' sowing (10th November) the lowest. For the soils tested, the highest and sustained crop production was obtained from Hamble soils (silt loam) compared with either the Fyfield (sandy) or Denchworth (clay). Adding nitrogen and other fertilisers would likely be necessary to take full advantage of the CO2 fertilisationeffect and to compensate, in some cases, for yield losses caused by climate change where water shortage becomes serious.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
AFRC: 1992, Environmental Change. 150 Years of Agricultural Research, Institute of Arable Crops Research, Rothmasted, Long Ashton, Broom's Barn, U.K., pp. 55-61.
Alexandrov, V. A.: 1997, 'Vulnerability of Agronomic Systems in Bulgaria', Clim. Change, 36, 135-149.
Allen, L. H., Baker, J. T., and Boote, K. J.: 1996, 'The CO2 Fertilization Effect: Carbohydrate Production and Retention as Biomass and Seed Yield', in Bazzaz, F. and Sombroek, W. (eds.), Global Climate Change and Agricultural Production, Direct and Indirect Effects of Changing Hydrological, Pedological and Plant Physiological Processes, FAO and John Wiley and Sons, pp. 65-100.
Bannayan, M. and Crout, N. M. J.: 1999, 'A Stochastic Modelling Approach for Real-Time Forecasting of Winter Wheat Yield', Field Crops Res. 62, 85-95.
Brown, R. A. and Rosenberg, N. J.: 1997, 'Sensitivity of Crop Yield and Water Use to Change in a Range of Climatic Factors and CO2 Concentrations: A Simulation Study Applying EPIC to the Central U.S.A.', Agric. For. Meteorol. 83, 171-203.
Butterfield, R. P., Harrison, J., Orr, M., and Gawith and Lonsdale, K.: 2000, 'Modelling Climate Change Impacts on Wheat, Potato and Grapevine in Great Britain', in Downing, T. E., Harrison, P. A., Butterfield, R. E., and Lonsdale, K. G. (eds.), Climate Change, Climate Variabliity and Agriculture in Europe—-An Integrated Assessment, Res. Report No. 21, Environmental Change Unit, Univ. of Oxford, 1A Mansfield Road, OX1 3TB, U.K., p. 445.
Climate Change Impacts Review Group CCIRG: 1996, Review of the Potential Effects of Climate Change in the United Kingdom, Second Report, HMSO, London.
Climate Change Impacts in the United Kingdom: 1998, The Agenda for Assessment and Action, The U.K. Climate Change Impacts Programme, Department of the Environment, Transport and the Regions (DETR).
Decker, W. L.: 1994, 'Developments in Agricultural Meteorology as a Guide to its Potential for the Twenty-First Century', Agric. For. Meteorol. 69, 9-25.
Donaldson, A., Hutley-Bull, P., and Webster, J. P. G.: 1994, The Effects of the Reform of the Common Agricultural Policy on Arable Farms in South East England, Farm Business Unit, Department of Agricultural Economics, Wye College, University of London.
GCCIP: 1997, Global Climate Change Information Programme, Department of Environmental and Geographical Sciences, Manchester, Metropolitan University.
Ghaffari, A., Cook, H. F., and Lee H. C.: 2001, 'Simulating Winter Wheat Yields under Temperate Conditions: Exploring Different Management Scenarios', Europ. J. Agronomy 15, 231-240.
Goudriaan, J. and de Ruiter, H. E.: 1983, 'Plant Growth in Response to CO2 Enrichment, at Two Levels of Nitrogen and Phosphorus Supply. 1. Dry Matter, Leaf Area and Development', Netherlands J. Agric. Sci. 31, 157-169.
Hammer, G. L., Butler, D. G., Muchow, R. C., and Meinke, H.: 1996, 'Integrating Physiological Understanding and Plant Breeding via Crop Modelling and Optimisation', in Cooper, M. and Hammer, G. L. (eds.), Plant Adaptation and Crop Improvement, CAB International, Wallingford, U.K., pp. 419-441.
Harrison, P. A. and Butterfield, R. E.: 1996, 'Effects of Climate Change on Europe-Wide Winter Wheat and Sunflower Productivity', Clim. Res. 7, 225-241.
Hunt, L. A. and Boote, K. J.: 1998, 'Data for Model Operation, Calibration, and Evaluation', in Tsuji, G. Y., Hoogenboom, G., and Thornton, P. K. (eds.), Understanding Options for Agricultural Production, Kluwer Academic Publishers, London, pp. 9-39.
Hutley-Bull, P.: 1993, Analysis of the Socio-Economic Impacts of Agricultural Reform in Certain European Regions: Competitiveness and Environmental Protection, Report of the Agronomic Component of EEC, (European Economic Community), Contract No. 4706A, Department of Agricultural Economics, Wye College, University of London, U.K.
Intergovernmental Panel on Climate Change (IPCC): 1996, Climate Change 1995: The Science of Climate Change, Cambridge University Press, Cambridge, U.K.
Intergovernmental Panel on Climate Change (IPCC): 2001, Climate Change 1995: The Scientific Basis of Climate Change, Cambridge University Press, Cambridge, U.K.
Jame, Y. W. and Cutforth, H. W.: 1996, 'Crop Growth Models for Decision Support Systems', Can. J. Plant Sci. 76, 9-19.
Jamieson, P. D., Porter, J. R., Goudriaan, J., Ritchie, J. T., van Keulen, H., and Stol, W.: 1998, 'A Comparison of the Models AFRCWHEAT2, CERES-Wheat, SIRIUS, SUCROS2 and SWHEAT with Measurements from Wheat Grown under Drought', Field Crops Res. 55, 23-44.
Jones, J. W.: 1993, 'Decision Support System for Agricultural Development', in Penning de Vries, F. W. T., Teng, P. Y. S., and Metselaar, K. (eds.), Systems Approaches for Agricultural Development, Kluwer Academic Publishers, Dordrecht, The Netherlands, pp. 459-471.
Keeling, C. D. and Whorf, T. P.: 1998, Atmospheric CO 2 Concentrations: Mauna Loa Observatory, Hawaii, 1958-1997, http://www.co2science.org/.
Kenny, G. J., Harrison, P. A., and Parry, M. L.: 1993, The Effect of Climate Change on the Agricultural and Horticultural Potential in Europe, Environmental Change Unit, University of Oxford, Research Report No. 2.
Lutze, J. L. and Gifford, R. M.: 1998, 'Acquisition and Allocation of Carbon and Nitrogen by Danthonia Richardsonii in Response to Restricted Nitrogen Supply and CO2 Enrichment', Plant Cell Environ. 21, pp. 1133-1141.
Matthews, R., Stephens, W., Hess, T., Mason, T., and Graves, A.: 2000, Applications of Crop/Soil Simulation Models in Developing Countries, Final Report, Institute of Water and Environment, Cranfield University, U.K.
Monteith, J. L.: 1981, 'Climatic Variation and the Growth of Crops', Quart. J. Roy. Meteorol. Soc. 107, 749-774.
Monteith, J. L.: 1996, 'The Quest for Balance in Crop Modelling', Agronomy J. 88, 695-697.
Moot, D. J., Henderson A. L., Porter J. R., and Semenov M. A.: 1996, 'Temperature, CO2 and the Growth and Development of Wheat: Changes in the Mean and Variability of Growing Conditions', Clim. Change 33, 351-358.
NIAB: 1997, Cereal Variety Handbook, National Institute of Agricultural Botany, U.K.
Parry, M. L., Kenny, G. J., and Harrison, P. A.: 1993, 'Aims and Methods', in Kenny, G. J., Harrison, P. A., and Parry, M. L. (eds.), The Effect of Climate Change on the Agricultural and Horticultural Potential in Europe, Environmental Change Unit, University of Oxford, Research Report No. 2, pp. 1-10.
Peiris, D. R., Crawford, J. W., Grashoff, C., Jefferies, R. A., Porter, J. R., and Marshall, B.: 1996, 'A Simulation Study of Crop Growth and Development under Climate-Change', Agric. For. Meteorol. 79, 271-287.
Rosenzweig, C. and Iglesias, A.: 1998, 'The Use of Crop Models for International Climate Change Impact Assessment', in Tsuji, G. Y., Hoogenboom, G., and Thornton, P. K. (eds.), Understanding Options for Agricultural Production, Kluwer Academic Publishers, London, pp. 267-292.
Semanov, M. A., Porter, J. R., and Delecolle, R.: 1993, 'Simulation of the Effects of Climate Change on Growth and Development of Wheat in the U.K. and France', in Kenny, G. J., Harrison, P. A., and Parry, M. L. (eds.), The Effect of Climate Change on the Agricultural and Horticultural Productivity Potential in Europe, Environmental Change Unit, University of Oxford, Research Report No. 2, pp. 121-136.
Semenov, M. A., Wolf, J., Evans, L. G., Eckersten, H., and Iglesias, A.: 1996, 'Comparison ofWheat Simulation Models under Climate Change. 2. Application of Climate Change Scenarios', Clim. Res. 7, 271-281.
Sionit, N., Mortensen, D. A., Strain, B. R., and Hellmers, H.: 1981, 'Growth Response of Wheat to CO2 Enrichment and Different Levels of Mineral Nutrition', Agronomy J. 73, 1023-1027.
Sylvester-Bradley, R., Scott, R. K., Clare, R. W., and Duffield, S. J.: 1998, Assessments of Wheat Growth to Support its Production and Improvement, HGCA, Vol. I, Project Report No. 151.
Sys, Ir. C., van Ranst, E., and Debaveye, J.: 1991, Land Evaluation. Part I. Principles in Land Evaluation and Crop Production Calculations, International Training Centre for Post-Graduate Soil Scientists, University Ghent.
Teng, P. S., Batchelor, W. D., Pinnschmidt, H. O., and Wilkerson, G. G.: 1998, 'Simulation of Pest Effects on Crops Using Coupled Pest-Crop Models: The Potential for Decision Support', in Tsuji, G. Y., Hoogenboom, G., and Thornton, P. K. (eds.), Understanding Options for Agricultural Production. Systems Approaches for Sustainable Agricultural Development, Kluwer Academic Publishers, Dordrecht, The Netherlands, pp. 221-266.
Totolo, O.: 1995, The Use of a Geographic Information System GIS (SPANS) to Facilitate Detailed Evaluation of Soil and Land, Ph.D. Thesis, Wye College, University of London.
Tubiello, F. N., Rosenzweig, C., and Volk, T.: 1995, 'Interactions of CO2, Temperature and Management Practices: Simulations with a Modified Version of CERES-Wheat', Agric. Systems 49, 135-152.
U.K. Climate Impacts Programme (UKCIP): 1998, Climate Change Scenarios for the United Kingdom, Summary Report, September 1998, U.K.
Wang, Y. P. and Connor, D. J.: 1996, 'Simulation of Optimal Development for Spring Wheat at Two Locations in Southern Australia under Present and Changed Climate Conditions', Agric. For. Meteorol. 79, 9-28.
Wassenaar, T., Lagacherie, P., Legros, J. P., and Rounsevell, M. D. A.: 1999, 'Modelling Wheat Yield Responses to Soil and Climate Variability at the Regional Scale', Clim. Res. 11, 209-220.
Watson, R. T., Zinyowera, M. C., and Moss, R. H.: 1998, The Regional Impacts of Climate Change: An Assessment of Vulnerability, Intergovernmental Panel on Climate Change, Cambridge University Press, Cambridge, U.K.
Wolf, J.: 1993, 'Effects of Climate Change on Wheat and Maize Production Potential in the EC', in Kenny, G. J., Harrison, P. A., and Parry, M. L. (eds.), The Effect of Climate Change on the Agricultural and Horticultural Potential in Europe, Environmental Change Unit, University of Oxford, Research Report No. 2, pp. 93-119.
Wolf, J., Evans, L. G., Semenov, M. A., Eckersten, H., and Iglesias, A.: 1996, 'Comparison ofWheat Simulation Models under Climate Change. 1.Model Calibration and Sensitivity Analyses', Clim. Res. 7, 253-270.
World Meteorological Organisation (WMO): 2000, WMO Statement on the Status of the Global Climate in 1999, WMO-No. 913, Geneva, p. 12.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Ghaffari, A., Cook, H.F. & Lee, H.C. Climate Change and Winter Wheat Management: A Modelling Scenario for South-Eastern England. Climatic Change 55, 509–533 (2002). https://doi.org/10.1023/A:1020784311916
Issue Date:
DOI: https://doi.org/10.1023/A:1020784311916