Neglected climatic variablesThe obs

Neglected climatic variables
The observed differences in the effect of high day temperature between experiments might largely be attributed to climatic variables such as RH, radiation, and wind modifying the effects of high temperature under natural conditions. These climatic variables, though very important, often receive little attention. For instance, the extent to which rice can fully use its ability to reduce canopy temperature under high ambient air temperature by transpirational cooling greatly depends on the RH─i.e., the vapor pressure deficit between the air and the tissue. When one compares a hot and dry location (Jakobabad, Pakistan) with a hot and humid site (Jessore, Bangladesh), the importance of RH and temperature interaction becomes evident (Fig. 2). In March, the eastern part of the Indo-Gangetic Plain has maximum day-temperature values ranging between 30 and 34 °C, with a high RH of 40−70% (this coincides with the hightemperature–sensitive flowering and early grain-filling stages of the dry-season crop [called boro in Bangladesh]). In September, when the rice crop is at a developmental stage similar to that in Bangladesh, the climate in Pakistan is characterized by high temperature (33–36 °C) and very low humidity (10–30%). Differences in RH will greatly affect the ability of the plants to employ evapotranspirational cooling to protect themselves from high-temperature damage. The second critical factor influencing yield is radiation. Although radiation is a component in most climate models, the empirical data used to predict future high-temperature effects on rice are mainly derived from studies conducted in controlled environments, where the amount of light provided in most cases is significantly low. Grain yield under field conditions was found to linearly increase up to 21 MJ m–2 (Peng et al 2004, Nagarajan et al 2010) (Fig. 3). The recently observed significant reduction in yield of IR72 under IRRI’s long-term trials in fully flooded conditions could possibly be explained by declining radiation. Climatic conditions, for example, light intensity, may be different, which may alter the effect of high day/night temperatures. Caution must be taken in using data to predict temperature effects on future climate. Moreover, a recent report has shown a substantial decrease in visibility across South and East Asia, South America, Australia, and Africa, resulting in global dimming over land (Wang et al 2009). Studies to quantify the effect of radiation and temperature interaction under field conditions are worth doing.
Wind speed, in combination with dry air conditions under fully irrigated conditions, facilitates rice cultivation at temperatures above 40 °C without any yield penalty. For instance, in Australia, Matsui et al (2007) recorded a reduction in canopy temperature by as much as 6.8 °C with the combination of hot and dry air, strong wind, and sufficient water, allowing rice production without reducing yields. Considering the local climate at target sites vulnerable to high temperature will be essential in dissecting the effects of different climatic parameters. Thisknowledge will help in the formulation of clear strategies to address yield losses due to increasing temperatures and to initiate breeding programs to develop high-temperature–tolerant rice for hot-humid and hot-dry regions.