Litcius/Paper detail

Thermography methods to assess stomatal behaviour in a dynamic environment

Silvère Vialet‐Chabrand, Tracy Lawson

2020Journal of Experimental Botany50 citationsDOIOpen Access PDF

Abstract

Although thermography allows rapid, non-invasive measurements of large numbers of plants, it has not been used extensively due to the difficulty in deriving biologically relevant information such as leaf transpiration (E) and stomatal conductance (gsw) from thermograms. Methods normalizing leaf temperature using temperatures from reference materials (e.g. with and without evaporative flux) to generate stress indices are generally preferred due to their ease of use to assess plant water status. Here, a simplified method to solve dynamic energy balance equations is presented, which enables the calculation of 'wet' and 'dry' leaf temperatures in order to derive stress indices, whilst providing accurate estimates of E and gsw. Comparing stress indices and gas exchange parameters highlights the limitation of stress indices in a dynamic environment and how this problem can be overcome using artificial leaf references with known conductance. Additionally, applying the equations for each pixel of a thermogram to derive the rapidity of stomatal response over the leaf lamina in wheat revealed the spatial heterogeneity of stomatal behaviour. Rapidity of stomatal movements is an important determinant of water use efficiency, and our results showed 'patchy' responses that were linked to both the spatial and temporal response of gsw.

Topics & Concepts

TranspirationStomatal conductanceThermographyBiological systemWater stressEvaporative coolerEnergy balanceEnvironmental scienceFlux (metallurgy)ConductanceMathematicsPhotosynthesisBotanyChemistryMeteorologyInfraredBiologyEcologyPhysicsOpticsOrganic chemistryCombinatoricsPlant Water Relations and Carbon DynamicsGreenhouse Technology and Climate ControlPlant responses to elevated CO2