Abstract
ABSTRACTCompared with a porometer, a thermal camera can be easily applied to large plant populations comprising a set of varieties, treatments, and replications, whereby, leaf temperature-based indicators are widely used to estimate stomatal conductance (gs); however, a major difficulty in applying these indicators is their vulnerability to meteorological conditions. In this study, a new indicator of gs (GsI) was developed with a modified theoretical equation of gs that was highly simplified by means of several assumptions. GsI calculation uses leaf and air temperature, relative humidity, and solar radiation measurements. To validate and compare GsI values with other thermal indicators as leaf-air temperature difference and crop water stress index, glasshouse and field experiments were conducted. Leaf temperature of cowpea plants was measured using a low-cost thermal camera to ensure a cost-friendly method. GsI proved to be more stable than other indicators, relative to the measured gs, irrespective of solar radiation, air temperature, and relative humidity conditions. As no reference temperature is needed for the calculation of GsI, it easily applies to large plant populations, although the GsI is most accurate in the range from moderate to high gs values (approximately, >0.2 mol m−2 s−1). We used GsI to evaluate a cowpea germplasm collection consisting of 248 accessions, and elucidated that most accessions with higher GsI, which expected to have higher gs, are originated in West-Africa. As GsI is available regardless of varying meteorological conditions, it is a useful indicator of gs, especially in field studies involving multilocation and time-course evaluations.Abbreviations: Cp: specific heat of the air; CWSI: crop water stress index; DAS: days after sowing; DT: saturated vapor pressure at temperature T; ea: vapor pressure of the air; es: vapor pressure at leaf surface; G: heat flux to the ground; ga: boundary layer conductance; gs: stomatal conductance; gv: total conductance; RH: relative humidity; Rn: net radiation; Rs: short-wave radiation; S: heat flux to the leaf; Ta: air temperature; Tdry: dry reference temperature; Ts: leaf surface temperature; Twet: wet reference temperature; VPD: vapor pressure deficit; γ: psychrometric constant; λE: latent heat flux; ρ: air density.
Highlights
Stomatal conductance is a major regulator of water vapor and carbon dioxide exchange between the leaf and the surrounding air, which directly affects plant growth
The highest values were observed in the afternoon at 51 days after sowing (DAS), when short-wave radiation (Rs) and Ta were higher during the measuring time-points (Table 1)
Except for leaf temperature, all other variables can be obtained from continuousmeasurement devices installed near the field; an evaluator only needs to take a thermal image for each measurement
Summary
Stomatal conductance is a major regulator of water vapor and carbon dioxide exchange between the leaf and the surrounding air, which directly affects plant growth. The most accurate method to measure stomatal conductance is by using a leaf porometer or an infrared gas analyzer. Such devices are not suitable for frequent measurement within large plant populations because individual measurements take on average 20‒ 60 s per leaf. Remote-sensing technologies are available to meet this demand, and infrared thermal imaging is widely used for the evaluation of stomatal conductance and transpiration rate at a scale varying from leaf to canopy (Costa, Grant & Chaves, 2013; Jones, 1999; Leinonen, Grant, Tagliavia, Chaves & Jones, 2006). Thermal imaging has been applied for evaluation of plant growth and drought stress, and that of nutrient status and disease infection (Guo et al, 2016; Stoll, Schultz & Berkelmann-Loehnertz, 2008)
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