A wheat canopy albedo high-throughput phenotyping method and its relationship with canopy architecture and leaf properties

Maria Francisca Ruz-Ruiz^1,2*Jose A. Jimenez-Berni³Richard Trethowan¹Helen Bramley¹

• ¹The University of Sydney, Sydney, Australia
• ²Institute for Sustainable Agriculture, Spanish National Research Council (CSIC), Córdoba, Spain
• ³Institute for Sustainable Agriculture, Spanish National Research Council (CSIC), Cordoba, Spain

Heat stress damage leads to yield penalties in many wheat growing areas. Climate change models predict warmer scenarios and more frequent heat shocks. Consequently, wheat breeders need to develop more productive varieties for warm conditions and therefore, identification of heat-tolerance traits is needed. Albedo is an integrative trait of the optical properties of the canopy defined as the ratio of reflected light to total light received. High albedos in warm conditions may help reduce damaging radiation. Despite its potential relevance for heat avoidance, albedo has been little explored in wheat breeding. In this work, a selection of thirty wheat (Triticum aestivum L.) genotypes of diverse origin were sown at two sowing dates in Australia (NSW) in 2018 and 2019. A high-throughput phenotyping method based on spectroradiometer measurements (Analytical Spectral Devices, ASD) to measure canopy albedo was developed to explore its relationship with temperature and other heat tolerance related traits. ASD albedo was validated with continuous albedometer measurements on a subset of genotypes. Data were captured at flowering (one of the most critical periods for heat-related damage). Genotypic differences for albedo were found in most environments. However, genotypic effects were most noticeable at noon in optimally sown materials (H2 0.71 – 0.86). Albedo was directly related to canopy architecture and light interception (r = 0.74) and varied depending on genotype and genotype by environment interaction. Air temperature in the canopy profile and canopy temperature (CT) were also monitored continuously in a subset of genotypes to explore the relationship between albedo and canopy micrometeorology. Canopies with higher albedos had larger air temperature differences across the canopy profile at flowering stage (r = 0.48). However, canopy temperature was not related to albedo even though it was strongly correlated (r = 0.99) to air temperature around the spike. Overall, these results indicate that canopy architecture is the primary influence on albedo under warm conditions. Although higher albedo was not associated with lower canopy temperature, its influence on canopy micrometeorology suggests that albedo may contribute to heat avoidance and could therefore be considered an additive trait for phenotyping and breeding for environments under high temperatures.