Arid directly affects crop growth and yield, such as reduces photosynthesis, weakens respiration rate, slows down the material transport, disorders stomatal switch, blocks the synthesis of chlorophyll, affects the cell wall and protein synthesis, etc., eventually leads to the reduction of output. How to solve this problem? This paper proposes a drought index based on thermal imaging technology. Canopy temperature distribution can reflect the growth of crops. And using thermal imaging technology can access to crop canopy temperature distribution quickly. Physiological indexes such as the changes of stomatal conductance and chlorophyll content is the important basis of crop drought resistance identification.So this paper studied the distribution of wheat canopy temperature with the change of stomatal conductance and chlorophyll content under drought conditions. The study was based on different drought resistant genotypes of winter wheat in Xinjiang with German JENOPTIK portable infrared thermal imager for canopy temperature information. The canopy leaf stomatal conductance and chlorophyll content was measured by SC-1 porosity meter and SPAD chlorophyll meter. Results prove that winter wheat canopy temperature decreases with the increase of stomatal conductance in dry conditions, which has a good linear relationship (r=-0.67). The correlation of canopy temperature and stomatal conductance of poor drought resistance(-0.93) is greater than that of good one(-0.46). There is significant difference between stomatal conductance and chlorophyll content of different drought resistance varieties(P<0.05). The variety of poor drought resistance is greater that of good one in morning-afternoon stomatal conductance change. And the chlorophyll content of the variety of good drought resistance is greater that of poor one. The conclusions above show that canopy temperature distribution has good correlation with the crop drought resistance indexes and can be used as an early indicator of drought resistance identification.This conclusion has important significance for drought resistance identification, the reasonable irrigation guidance and improving the water use efficiency.
[1]
Liu Guo-jie.
The Relationship of Grape Leaf Stomatal Conductance and Water Potential with Leaf Position Under Drought Conditions
,
2013
.
[2]
Toshiyuki Takai,et al.
Canopy temperature on clear and cloudy days can be used to estimate varietal differences in stomatal conductance in rice
,
2010
.
[3]
H. Jones,et al.
Thermal infrared imaging of crop canopies for the remote diagnosis and quantification of plant responses to water stress in the field.
,
2009,
Functional plant biology : FPB.
[4]
Weixing Cao,et al.
Quantitative relationships between canopy spectral reflectance and leaf stomatal conductance in rice
,
2006
.
[5]
Wei Zhuang,et al.
Parameterization of water response functions in leaf stomatal conductance model for winter wheat
,
2013
.