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Simulating winter wheat shoot apex phenology

Published online by Cambridge University Press:  27 March 2009

G. S. McMaster
Affiliation:
USDA–ARS, Crops Research Laboratory, 1701 Centre Avenue, Fort Collins, CO 80526, USA
W. W. Wilhelm
Affiliation:
USDA–ARS, Agronomy Department, University of Nebraska, Lincoln, NE 68583, USA
J. A. Morgan
Affiliation:
USDA–ARS, Crops Research Laboratory, 1701 Centre Avenue, Fort Collins, CO 80526, USA

Summary

Simulation models are heuristic tools for integrating diverse processes and help to increase our understanding of complex processes and systems. Models that predict crop development can serve as decision-support tools in crop management. This paper describes a phenology simulation model for the winter wheat shoot apex and reports validation and sensitivity analysis results.

The complete developmental sequence of the winter wheat shoot apex is quantitatively outlined and correlated with commonly recognised phenological growth stages. The phyllochron is used to measure the thermal time between most phenological growth stages, thereby increasing the flexibility over the growing degree-day (GDD) and photothermal approaches. Nineteen site-years covering a range of climatic conditions, cultural practices and cultivars across the Central Great Plains, USA, are used to validate the model.

Validation results show that the predicted phyllochron (108 GDD) agrees well with the observed phyllochron (107 GDD) for ten cultivars. Mean seedling emergence is predicted to within 2 days in almost all of the 19 site-years. The ability of the model to predict growth stages accurately increased successively from jointing to heading to maturity. Maturity is generally predicted to within 5 days of the observed day.

After validation, recalibration of the phyllochron estimates between growth stages are provided, and corrections for mesic and xeric conditions are suggested. Further validation of the entire developmental sequence of the shoot apex is recommended.

Type
Crops and Soils
Copyright
Copyright © Cambridge University Press 1992

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References

Baker, C. K., Gallagher, J. N. & Monteith, J. L. (1980). Daylength change and leaf appearance in winter wheat. Plain, Cell and Environment 3, 285287.CrossRefGoogle Scholar
Batten, G. D. & Khan, M. A. (1987). Effect of time of sowing on grain yield, and nutrient uptake of wheats with contrasting phenology. Australian Journal of Experimental Agriculture 27, 881887.CrossRefGoogle Scholar
Bauer, A., Frank, A. B. & Black, A. L. (1983). Correlation of five wheat growth stage scales used in the Great Plains. USDA AAT–NC–7.Google Scholar
Belford, R. K., Klepper, B. & Rickman, R. W. (1987). Studies of intact shoot–root systems of field-grown winter wheat. II. Root and shoot developmental patterns as related to nitrogen fertilizer. Agronomy Journal 79, 310319.CrossRefGoogle Scholar
Bhullar, S. S. & Jenner, C. F. (1983). Responses to brief periods of elevated temperature in ears and grains of wheat. Australian Journal of Plant Physiology 10, 549560.Google Scholar
Bonnett, O. T. (1966). Inflorescences of maize, wheat, rye, barley, and oats: Their initiation and development. Bulletin of the University of Illinois Agricultural Experiment Station 721.Google Scholar
Boone, M. Y. L., Rickman, R. W. & Whisler, F. D. (1990). Leaf appearance rates of two winter wheat cultivars under high carbon dioxide conditions. Agronomy Journal 82, 718724.CrossRefGoogle Scholar
Crofts, H. J., Gardner, W. K. & Velthuis, R. G. (1984). A phenological evaluation of wheat for South-western Victoria. Australian Journal of Agricultural Research 35, 521528.CrossRefGoogle Scholar
Delecolle, R., Couvreur, F., Pluchard, F. P. & Varlet-Grancher, C. (1985). About the leaf-daylength model under French conditions. In Wheat Growth and Modelling (Eds Day, W. & Atkin, R. K.), pp. 2532. New York: Plenum Press.CrossRefGoogle Scholar
Delecolle, R., Hay, R. K. M., Guerif, M., Pluchard, P. & Varlet-Grancher, C. (1989). A method of describing the progress of apical development in wheat, based on the time-course of organogenesis. Field Crops Research 21, 147160.CrossRefGoogle Scholar
French, V. & Hodges, T. (1985). Comparison of crop phenology models. Agronomy Journal 11, 170171.CrossRefGoogle Scholar
Friend, D. J. C. (1965). Tillering and leaf production in wheat as affected by temperature and light intensity. Canadian Journal of Botany 43, 10631076.Google Scholar
Gallagher, J. N. (1979). Field studies of cereal leaf growth. I. Initiation and expansion in relation to temperature and ontogeny. Journal of Experimental Botany 30, 625636.CrossRefGoogle Scholar
Gallagher, J. N., Biscoe, B. V. & Wallace, J. S. (1979). Field studies of cereal leaf growth. IV. Winter wheat leaf extension in relation to temperature and leaf water status. Journal of Experimental Botany 30, 657668.CrossRefGoogle Scholar
Haley, S. (1989). Variation among winter wheats for traits associated with drought resistance. MS thesis, Colorado State University.Google Scholar
Haun, J. R. (1973). Visual quantification of wheat development. Agronomy Journal 65, 116119.Google Scholar
Hay, R. K. M. & Delecolle, R. (1989). The setting of rates of development of wheat plants at crop emergence: influence of the environment on rates of leaf appearance. Annals of Applied Biology 115, 333341.CrossRefGoogle Scholar
Hay, R. K. M. & Wilson, G. T. (1982). Leaf appearance and extension in field-grown winter wheat plants: the importance of soil temperature during vegetative growth. Journal of Agricultural Science, Cambridge 99, 403410.Google Scholar
Herzog, H. (1986). Source and Sink During the Reproductive Period of Wheat. Development and its Regulation With Special Reference to Cytokinins. Berlin: Paul Parey Science Publishers.Google Scholar
Kirby, E. J. M. (1985). Significant stages of ear development in winter wheat. In Wheat Growth and Modelling (Eds Day, W. & Atkin, R. K.), pp. 724. New York: Plenum Press.CrossRefGoogle Scholar
Kirby, E. J. M. & Perry, M. W. (1987). Leaf emergence rates of wheat in a Mediterranean environment. Australian Journal of Agricultural Research 38, 455464.CrossRefGoogle Scholar
Kirby, E. J. M., Appleyard, M. & Fellowes, G. (1982 a). Effect of sowing date on the temperature response of leaf emergence and leaf size in barley. Plant, Cell and Environment 5, 477484.CrossRefGoogle Scholar
Kirby, E. J. M., Appleyard, M. & Fellowes, G. (1985 a). Effect of sowing date and variety on main shoot leaf emergence and number of leaves of barley and wheat. Agronomie 5, 117126.CrossRefGoogle Scholar
Kirby, E. J. M., Appleyard, M. & Fellowes, G. (1985 b). Leaf emergence and tillering in barley and wheat. Agronomie 5, 193200.Google Scholar
Kirby, E. J. M., Siddique, K. H. M., Perry, M. W., Kaesehagen, D. & Stern, W. R. (1989). Variation in spikelet initiation and ear development of old and modern Australian wheat varieties. Field Crops Research 20, 113128.CrossRefGoogle Scholar
Klepper, B., Rickman, R. W. & Peterson, C. M. (1982). Quantitative characterization of vegetative development in small cereal grains. Agronomy Journal 74, 789792.Google Scholar
Klepper, B., Rickman, R. W. & Belford, R. K. (1983). Leaf and tiller identification on wheat plants. Crop Science 23, 10021004.CrossRefGoogle Scholar
Klepper, B., Belford, R. K. & Rickman, R. W. (1984). Root and shoot development in winter wheat. Agronomy Journal 16, 117122.Google Scholar
Klepper, B., Frank, A. B., Bauer, A. & Morgan, J. A. (1985). Physiological and phenological research in support of wheat yield modeling. In ARS Wheat Yield Project (Coordinator Willis, W. O.), pp. 134150. USDA–ARS, ARS–38. Springfield, VA: National Technical Information Service.Google Scholar
Malvoisin, P. (1984). Organogenesis and growth of the main culm of wheat from sowing to flowering. I. Relationships between leaf growth and the differentiation of young leaves of flowers. Agronomie 4, 557564.CrossRefGoogle Scholar
Masle-Meynard, J. & Sebillotte, M. (1981). Heterogeneity of a winter wheat stand. I. Concept of stand structure. Agronomie 1, 207216.Google Scholar
Masoni, A., Ercoli, L. & Massantini, F. (1990). Relationship between number of days, growing degree days and photothermal units and growth in wheat (Triticum aestivumL.) according to seeding time. Agricoltura Mediterranea 120, 4151.Google Scholar
McMaster, G. S. & Smika, D. E. (1988). Estimation and evaluation of winter wheat phenology in the central Great Plains. Agricultural and Forest Meteorology 43, 118.Google Scholar
McMaster, G. S., Klepper, B., Rickman, R. W., Wilhelm, W. W. & Willis, W. O. (1991). Simulation of aboveground vegetative development and growth of unstressed winter wheat. Ecological Modeling 53, 189204.CrossRefGoogle Scholar
Nuttonson, M. Y. (1948). Some preliminary observations of phenological data as a tool in the study of photoperiodic and thermal requirements of various plant material. In Vernalization and Photoperiodism Symposium (Eds Murneek, A. E. & Whyte, R. O.), pp. 129143. Chronica Botanica.Google Scholar
Nuttonson, M. Y. (1955). Wheat-Climate Relationships. Washington, DC: American Institute of Crop Ecology.Google Scholar
Oosterhuis, D. M. (1977). Developmental morphology of the spike of a Rhodesian spring wheat recorded with a scanning electron microscope. Rhodesian Journal of Agricultural Research 15, 6577.Google Scholar
Rawson, H. M. & Evans, L. T. (1970). The pattern of grain growth within the ear of wheat. Australian Journal of Biological Science 23, 753764.CrossRefGoogle Scholar
Rawson, H. M., Hindmarsh, J. H., Fischer, R. A. & Stockman, Y. M. (1983). Changes in leaf photosynthesis with plant ontogeny and relationships with yield per ear in wheat cultivars and 120 progeny. Australian Journal of Plant Physiology 10, 503514.Google Scholar
Rickman, R. W. & Klepper, E. L. (1991). Tillering in wheat. In Plant Phenology (Ed Hodges, T.), pp. 7384. Boca Raton: CRC Press.Google Scholar
Ritchie, J. T. & Otter, S. (1985). Description and performance of CERES–Wheat: a user-oriented wheat yield model. In ARS Wheat Yield Project (Coordinator Willis, W. O.), pp. 159175. USDA Agricultural Research Service, ARS–38. Springfield, VA: National Technical Information Service.Google Scholar
Saini, A. D., Dadhwal, V. K., Phadnawis, B. N. & Nanda, R. (1986). Influence of sowing dates on pre-anthesis phenology in wheat. Indian Journal of Agricultural Science 56, 503511.Google Scholar
Sayed, H. I. & Ghandorah, M. O. (1984). Association of grain-filling characteristics with grain weight and senescence in wheat under warm dry conditions. Field Crops Research 9, 323332.Google Scholar
Spiertz, J. H. J. & Vos, J. (1985). Grain growth of wheat and its limitation by carbohydrate and nitrogen supply. In Wheat Growth and Modelling (Eds Day, W. & Atkin, R. K.), pp. 129142. New York: Plenum Press.CrossRefGoogle Scholar
Thomson, W. J. (1986). Effect of sowing date on the development of three winter wheat cultivars. Tests of Agrochemicals and Cultivars, No. 7 (Annals of Applied Biology, Supplement), 182183.CrossRefGoogle Scholar
Vos, J. (1985). Aspects of modelling post-floral growth of wheat and calculations of the effects of temperature and radiation. In Wheat Growth and Modelling (Eds Day, W. & Atkin, R. K.), pp. 143148. New York: Plenum Press.Google Scholar
Weir, A. H., Bragg, P. L., Porter, J. R. & Rayner, J. H. (1984). A winter wheat crop simulation model without water or nutrient limitations. Journal of Agricultural Science, Cambridge 102, 371382.CrossRefGoogle Scholar
Wiegand, C. L. & Cuellar, J. A. (1981). Duration of grain filling and kernel weight of wheat as affected by temperature. Crop Science 21, 95101.Google Scholar
Wilhelm, W. W., McMaster, G. S., Klepper, B. & Rickman, R. W. (1990). Vegetative development and growth model for wheat. In Climatic Risk in Crop Production: Models and Management for the Semi-Arid Tropics and Subtropics, An International Symposium and Workshop (Eds Muchow, R. C. & Bellamy, J. A.), pp. 3435. Brisbane, Australia: Incitec.Google Scholar
Wright, D. & Hughes, Ll.G. (1987). Relationships between time, temperature, daylength and development in spring barley. Journal of Agricultural Science, Cambridge 109, 365373.CrossRefGoogle Scholar