Your search found 15 records
(Location: IWMI-HQ Call no: PER Record No: H06884)
(Location: IWMI-HQ Call no: PER Record No: H06885)
3 Thorburn, P. J.. 1990. Interpretation of solute profile dynamics in irrigated soils: III - A simple model of bypass flow in soils. Irrigation Science, 11(4):219-225.
(Location: IWMI-HQ Call no: PER Record No: H06886)
(Location: IWMI-HQ Call no: P 4264 Record No: H018715)
5 Cramer, V. A.; Thorburn, P. J.; Fraser, G. W. 1999. Transpiration and groundwater uptake from farm forest plots of Casuarina glauca and Eucalyptus camaldulensis in saline areas of southeast Queensland, Australia. Agricultural Water Management, 39(2/3):187-204.
(Location: IWMI-HQ Call no: PER Record No: H023941)
6 Zhang, L.; Dawes, W. R.; Slavich, P. G.; Meyer, W. S.; Thorburn, P. J.; Smith, D. J.; Walker, G., R. 1999. Growth and ground water uptake responses of lucerne to changes in groundwater levels and salinity: Lysimeter, isotope and modelling studies. Agricultural Water Management, 39(2/3):265-282.
(Location: IWMI-HQ Call no: PER Record No: H023945)
7 Thorburn, P. J.; Cook, F. J.; Bristow, K. L. 2002. New water-saving production technologies: Advances in trickle irrigation. In Yajima, M.; Okada, K.; Matsumoto, N. (Eds.), Water for sustainable agriculture in developing regions û More crop for every scarce drop: Proceedings of the 8th JIRCAS International Symposium, Tsukuba, 27-28 November 2001. Ibaraki, Japan: JIRCAS. pp.53-62.
(Location: IWMI-HQ Call no: 631.7.2 G000 YAJ Record No: H031513)
(Location: IWMI-HQ Call no: PER Record No: H033545)
(Location: IWMI-HQ Call no: PER Record No: H033547)
(Location: IWMI-HQ Call no: PER Record No: H033548)
(Location: IWMI-HQ Call no: PER Record No: H033550)
(Location: IWMI-HQ Call no: PER Record No: H033556)
(Location: IWMI-HQ Call no: PER Record No: H034194)
(Location: IWMI-HQ Call no: PER Record No: H038540)
15 Asseng, S.; Ewert, F.; Martre, P.; Rotter, R. P.; Lobell, D. B.; Cammarano, D.; Kimball, B. A.; Ottman, M. J.; Wall, G. W.; White, J. W.; Reynolds, M. P.; Alderman, P. D.; Prasad, P. V. V.; Aggarwal, Pramod Kumar; Anothai, J.; Basso, B.; Biernath, C.; Challinor, A. J.; De Sanctis, G.; Doltra, J.; Fereres, E.; Garcia-Vila, M.; Gayler, S.; Hoogenboom, G.; Hunt, L. A.; Izaurralde, R. C.; Jabloun, M.; Jones, C. D.; Kersebaum, K. C.; Koehler, A-K.; Muller, C.; Kumar, S. N.; Nendel, C.; O’Leary, G.; Olesen, J. E.; Palosuo, T.; Priesack, E.; Rezaei, E. E.; Ruane, A. C.; Semenov, M. A.; Shcherbak, I.; Stockle, C.; Stratonovitch, P.; Streck, T.; Supit, I; Tao, F.; Thorburn, P. J.; Waha, K.; Wang, E.; Wallach, D.; Wolf, J.; Zhao, Z.; Zhu, Y. 2015. Rising temperatures reduce global wheat production. Nature Climate Change, 5:143-147. [doi: https://doi.org/10.1038/nclimate2470]
(Location: IWMI HQ Call no: e-copy only Record No: H046906)
Crop models are essential tools for assessing the threat of climate change to local and global food production1. Present models used to predict wheat grain yield are highly uncertain when simulating how crops respond to temperature2. Here we systematically tested 30 different wheat crop models of the Agricultural Model Intercomparison and Improvement Project against field experiments in which growing season mean temperatures ranged from 15 °C to 32 °C, including experiments with artificial heating. Many models simulated yields well, but were less accurate at higher temperatures. The model ensemble median was consistently more accurate in simulating the crop temperature response than any single model, regardless of the input information used. Extrapolating the model ensemble temperature response indicates that warming is already slowing yield gains at a majority of wheat-growing locations. Global wheat production is estimated to fall by 6% for each °C of further temperature increase and become more variable over space and time.
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