Temperature gradient chambers for research on global environment change. III. A system designed for rice in Kyoto, Japan

Synthesis and validation of crop models for assessment of of the impact of elevated atmospheric CO 2 concentration and anticipated global warming on crop production require crop response data obtained under field‐like conditions. The temperature gradient chamber (TGC) with the facility for CO 2 enrichment allows the creation of various CO 2 and temperature regimes for crops over the entire growth period with relatively inexpensive construction and running costs. The TGC develops a temperature gradient along its longitudinal axis using solar energy during the day and heating at night while maintaining the natural diurnal cycle. The temperature gradient and the CO 2 concentration in the TGC are regulated by computer control of the air ventilation rate through the TGC and of the CO 2 release rate. Longitudinal gradients of CO 2 concentration and water vapour pressure deficit of air in the TGC were generally less than 5% and ±0.2 kPa, respectively. A CO 2 enrichment experiment on rice in the TGC showed that a doubling of the CO 2 concentration markedly enhanced crop dry matter production. Temperature had less effect on dry matter production, although panicle dry weight was greatly decreased at higher temperature as a result of high‐temperature‐induccd sterility of rice spikelets. Since rice spikclets are most sensitive to high temperature at the moment of flowering, and their flowering habit is highly synchronized with the diurnal courses of environmental conditions, the TGC is a useful tool in understanding rice responses to changes in atmosphere and temperature.