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REFERENCES

  • Adachi F. , Kobata T. , Arimoto M. & Imaki T. (1995) Comparison of water use efficiency of paddy rice (Oryza sativa L.) among locations and interannual variation in humid areas. 1. Reliability of estimated canopy transpiration rate from meteorological and physiological data of the crop. Japanese Journal of Crop Science 64, 509515 (in Japanese with English abstract).
  • Amani I. , Fischer R.A. & Reynolds M.P. (1996) Canopy temperature depression association with yield of irrigated spring wheat cultivars in a hot climate. Journal of Agronomy and Crop Science 176, 119129.
  • Amthor J.S. (1989) Respiration and Crop Productivity. Springer-Verlag, New York, USA.
  • Araus J.L. , Slafer G.A. , Reynolds M.P. & Royo C. (2002) Plant breeding and drought in C3 cereals: what should we breed for? Annals of Botany 89, 925940.
  • Fischer R.A. , Rees D. , Sayre K.D. , Lu Z.-M. , Condon A.G. & Larque Saavedra A. (1998) Wheat yield progress associated with higher stomatal conductance and photosynthetic rate, and cooler canopies. Crop Science 38, 14671475.
  • Garrity D.P. & O'Toole J.C. (1995) Selection for reproductive stage drought avoidance in rice, using infrared thermometry. Agronomy Journal 87, 773779.
  • Hall A.E. , Richards R.A. , Condon A.G. , Wright G.C. & Farquhar G.D. (1994) Carbon isotope discrimination and plant breeding. Plant Breeding Reviews 12, 81113.
  • Homma K. , Nakagawa H. , Horie T. , Ohnishi H. , Kim H. & Ohnishi M. (1999) Energy budget and transpiration characteristics of rice grown under elevated CO2 and high temperature conditions as determined by remotely sensed canopy temperatures. Japanese Journal of Crop Science 68, 137145 (in Japanese with English abstract).
  • Horie T. (1978) Studies on photosynthesis and primary production of rice plants in relation to meteorological environments. I. Gaseous diffusive resistances, photosynthesis and transpiration in the leaves as influenced by radiation intensity and wind speed. Journal of Agricultural Meteorology 34, 125136.
  • Horie T. , Lubis I. , Takai T. , Ohsumi A. , Kuwasaki K. , Katsura K. & Nii A. (2003) Physiological traits associated with high yield potential in rice. In Rice Science: Innovations and Impact for Livelihood (eds T.W.Mew , D. S.Brar , S.Peng , D.Dawe & B.Hardy ), pp. 117145. IRRI, Los Baños, Philippines.
  • Inoue Y. (1986) Remote-monitoring of function and state of crop community. I. Analysis of thermal image of crop canopy. Japanese Journal of Crop Science 55, 261268 (in Japanese with English abstract).
  • Jackson R.D. , Idso S.B. , Reginato R.J. & Pinter P.J. Jr. (1981) Canopy temperature as a crop water stress indicator. Water Resources Research 17, 11331138.
  • Jones H.G. (1999) Use of thermography for quantitative studies of spatial and temporal variation of stomatal conductance over leaf surfaces. Plant, Cell and Environment 22, 10431055.
  • Kuroda E. & Kumura A. (1990) Difference in single leaf photosynthesis between old and new rice varieties. I. Single-leaf photosynthesis and its dependence on stomatal conductance. Japanese Journal of Crop Science 59, 283292 (in Japanese with English abstract).
  • Lu Z. , Radin J.W. , Turcotte E.L. , Percy R. & Zeiger E. (1994) High yields in advanced lines of pima cotton are associated with higher stomatal conductance, reduced leaf area and lower leaf temperature. Physiologia Plantarum 92, 266272.
  • Miflin B. (2000) Crop improvement in the 21st century. Journal of Experimental Botany 51, 18.
  • Monteith J.L. (1973) Principles of Environmental Physics. Edward Arnold, London, UK.
  • Paw U K.T. , Qiu J. , Su H.-B. , Watanabe T. & Brunet Y. (1995) Surface renewal analysis: a new method to obtain scalar fluxes. Agricultural and Forest Meteorology 74, 119137.
  • Peng S. & Khush G.S. (2003) Four decades of breeding for varietal improvement of irrigated lowland rice in the International Rice Research Institute. Plant Production Science 6, 157164.
  • Peng S. , Cassman K.G. , Virmani S.S. , Sheehy J. & Khush G.S. (1999) Yield potential trends of tropical rice since the release of IR8 and the challenge of increasing rice yield potential. Crop Science 39, 15521559.
  • Reynolds M.P. , Rajaram S. & Sayre K.D. (1999) Physiological and genetic changes of irrigated wheat in the post-green revolution period and approaches for meeting projected global demand. Crop Science 39, 16111621.
  • Richards R.A. (2000) Selectable traits to increase crop photosynthesis and yield of grain crops. Journal of Experimental Botany 51, 447458.
  • Sakuratani T. & Horie T. (1985) Studies on evapotranspiration from crops. (1) On seasonal changes, varietal differences and the simplified methods of estimate in evapotranspiration of paddy rice. Journal of Agricultural Meteorology 41, 4555 (in Japanese with English summary).
  • Takai T. , Matsuura S. , Nishio T. , Ohsumi A. , Shiraiwa T. & Horie T. (2005) Rice yield potential is closely related to crop growth rate during late reproductive period. Field Crops Research 10.1016/j.fcr.2005.08.001
  • Takechi O. , Haseba T. , Tomari I. & Akimoto T. (1962) Studies on the leaf temperature (1) Influences of solar radiation and wind velocity on the leaf temperature of citrus. Journal of Agricultural Meteorology 18, 8991 (in Japanese with English summary).
  • Tolk J.A. , Howell T.A. , Steiner J.L. & Krieg D.R. (1995) Aerodynamic characteristics of corn as determined by energy balance techniques. Agronomy Journal 87, 464473.
  • Wong S.-C. , Cowan I.R. & Farquhar G.D. (1985) Leaf conductance in relation to rate of CO2 assimilation. Plant Physiology 78, 821825.
  • Yoshida S. & Coronel V. (1976) Nitrogen nutrition, leaf resistance, and leaf photosynthetic rate of the rice plant. Soil Science and Plant Nutrition 22, 207211.