Press Release
Free Access
Issue
Agron. Sustain. Dev.
Volume 27, Number 2, April-June 2007
Page(s) 79 - 87
DOI https://doi.org/10.1051/agro:2006035
Published online 23 March 2007
References of  Agron. Sustain. Dev. 27 (2007) 79-87
  1. Andre M., Du Cloux H. (1993) Interaction of CO2 enrichment and water limitations on photosynthesis and water efficiency in wheat, Plant Physiol. Bioch. 31, 103-112.
  2. Baker J.T., Allen L.H., Boote K.J., Pickering N.B. (1997) Rice responses to drought under carbon dioxide enrichment. 1. Growth and yield, Global Change Biol. 3, 119-128.
  3. Brisson N., Casals M.L. (2005) Leaf dynamics and crop water status throughout the growing cycle of durum wheat crops grown in two contrasted water budget conditions, Agron. Sustain. Dev. 25, 151-158 [EDP Sciences] [CrossRef].
  4. Burkart S., Manderscheid R., Weigel H.J. (2004) Interactive effects of elevated atmospheric CO2-concentrations and plant available soil water content on canopy evapotranspiration and conductance of spring wheat, Eur. J. Agron. 21, 401-417 [CrossRef].
  5. Chaudhuri U.N., Kirkham M.B., Kanemasu E.T. (1990) Carbon dioxide and water level effects on yield and water use of winter wheat, Agron. J. 82, 637-641.
  6. Clifford S.C., Stronach I.M., Mohamed A.D., Azamali S.N., Crout N.M.J. (1993) The effects of elevated atmospheric carbon dioxide and water stress on light interception, dry matter production and yield in stands of groundnut (Arachis hypogaea L.), J. Exp. Bot. 44, 1763-1770 [CrossRef].
  7. Foulkes M.J., Scott R.K., Sylvester-Bradley R. (2001) The ability of wheat cultivars to withstand drought in UK conditions: formation of grain yield, J. Agr. Sci. 38, 153-169.
  8. Gifford R.M. (1979) Growth and yield of CO2-enriched wheat under water-limited conditions, Aust. J. Plant Physiol. 6, 367-378.
  9. Gregory J.M., Mitchell J.F.B., Brady A.J. (2003) Summer drought in northern midlatitudes in a time-dependent CO2 climate experiment, J. Climate 10, 662-686 [CrossRef].
  10. Houghton J.T., Ding Y., Griggs D.J., Noguer M., van der Linden P.J., Dai X., Maskell K., Johnson C.A. (2001) Climate Change 2001: The scientific basis. Intergovernmental Panel on Climate Change 2001, Cambridge University Press, Cambridge.
  11. Hunsaker D.J., Kimball B.A., Pinter P.J., Lamorte R.L., Wall G.W. (1996) Carbon dioxide enrichment and irrigation effects on wheat evapotranspiration and water use efficiency, T. ASAE 39, 1345-1355.
  12. Idso K.E., Idso S.B. (1994) Plant responses to atmospheric CO2 enrichment in the face of environmental constraints - A review of the past 10 years research, Agr. Forest Meteorol. 69, 153-203 [CrossRef].
  13. Jamieson P.D., Martin R.J., Francis G.S., Wilson D.R. (1995) Drought effects on biomass production and radiation-use efficiency in barley, Field Crop. Res. 43, 77-86.
  14. Jamieson P.D., Porter J.R., Goudriaan J., Ritchie J.T., Vankeulen H., Stol W. (1998) A comparison of the models AFRCWHEAT2, CERES-wheat, Sirius, SUCROS2 and SWHEAT with measurements from wheat grown under drought, Field Crop. Res. 55, 23-44.
  15. Kang S., Zhang F., Hu X., Zhang J. (2002) Benefits of CO2 enrichment on crop plants are modified by soil water, Plant Soil 239, 59-77.
  16. Kimball B.A., Pinter P.J., Garcia R.L., Lamorte R.L., Wall G.W., Hunsaker D.J., Wechsung G., Wechsung F., Kartschall T. (1995) Productivity and water use of wheat under free-air CO2 enrichment, Global Change Biol. 1, 429-442.
  17. Manderscheid R., Burkart S., Bramm A., Weigel H.J. (2003) Effect of CO2 enrichment on growth and daily radiation use efficiency of wheat in relation to temperature and growth stage, Eur. J. Agron. 19, 41-425 [CrossRef].
  18. Miller A., Tsai C.H., Hemphill D., Endres M., Rodermel S., Spalding M. (1997) Elevated CO2 effects during leaf ontogeny - A new perspective on acclimation, Plant Physiol. 115, 1195-1200 [PubMed].
  19. Mitchell R.A.C., Mitchell V.J., Lawlor D.W. (2001) Response of wheat canopy CO2 and water gas-exchange to soil water content under ambient and elevated CO2, Global Change Biol. 7, 599-611.
  20. O'Connell M.G., O'Leary G.J., Whitfield D.M., Connor D.J. (2004) Interception of photosynthetically active radiation and radiation-use efficiency of wheat, field pea and mustard in a semi-arid environment, Field Crop. Res. 85, 111-124.
  21. Ommen O.E., Donnelly A., Vanhoutvin S., van Oijen M., Manderscheid R. (1999) Chlorophyll content of spring wheat flag leaves grown under elevated CO2 concentrations and other environmental stresses within the ESPACE-wheat project, Eur. J. Agron. 10, 197-20 [CrossRef].
  22. Pinter P.J., Kimball B.A., Mauney J.R., Hendrey G.R., Lewin K.F., Nagy J. (1994) Effects of free-air carbon dioxide enrichment on PAR absorption and conversion efficiency by cotton, Agr. Forest Meteorol. 70, 209-230 [CrossRef].
  23. Pinter P.J., Kimball B.A., Garcia R.L., Wall G.W., Hunsaker D.J., Lamorte R.L. (1996) Free-air CO2 enrichment: Responses of cotton and wheat crops, in: Koch G.W., Mooney H.A. (Eds.), Carbon Dioxide and Terrestrial Ecosystems, Academic Press, San Diego, pp. 215-247.
  24. Polley H.W. (2002) Implications of atmospheric and climatic change for crop yield and water use efficiency, Crop Sci. 42, 131-140 [PubMed].
  25. Rogers H.H., Cure J.D., Smith J.M. (1986) Soybean growth and yield response to elevated carbon dioxide, Agr. Ecosyst. Environ. 16, 113-128 [CrossRef].
  26. Sadras V.O., Milroy S.P. (1996) Soil-water thresholds for the responses of leaf expansion and gas exchange: A review, Field Crop. Res. 47, 253-266.
  27. Samarakoon A.B., Muller W.J., Gifford R.M. (1995) Transpiration and leaf area under elevated CO2: effects of soil water status and genotype in wheat, Aust. J. Plant Physiol. 22, 33-44.
  28. Sionit N., Hellmers H., Strain B.R. (1980) Growth and yield of wheat under CO2 enrichment and water stress, Crop. Sci. 20, 687-690.
  29. Stone P.J., Wilson D.R., Reid J.B., Gillespie R.N. (2001) Water deficit effects on sweet corn. I. Water use, radiation use efficiency, growth, and yield, Aust. J. Agr. Res. 52, 103-113 [CrossRef].
  30. Weigel H.J., Mejer G.J., Jäger H.J. (1992) Impact of climate change on agriculture - Open-top chambers as a tool to investigate long-term effects of elevated CO2 levels on plants, J. Appl. Bot. 66, 135-142.