B51D-0450
Estimating Mesophyll Conductance in the Tropical Rainforest

Friday, 18 December 2015
Poster Hall (Moscone South)
Ingrid Coughlin, University of Sao Paulo, Sao Paulo, United States
Abstract:
In the current research modeling the carbon cycle, some of the biggest setbacks are methodological barriers to calculating the gross primary production (GPP) in the terrestrial biosphere. However, recent developments in high precision gas measurements now allow the use of COS as a potential tracer for determination of GPP, independently of CO2 .Since the tropics are implicated as being the source of the most significant reduction of carbon uptake by the majority of models, making accurate GPP measurements in the tropics is particularly important for carbon modeling. In order to constrain measurements of GPP in the tropics, carbonyl sulfide fluxes on a leaf chamber scale and a canopy-wide scale will be analyzed in a field site in the central Amazon. Accompanying this experiment, I am measuring the resistance of CO2 passing  through the intercellular airspaces in the leaf to the sites of carboxylation, known as mesophyll conductance. Mesophyll conductance is poorly documented in the tropics, and remains a centrally limiting factor in plant uptake of COS and CO2 – with upward estimates of 40% of the CO2 diffusional limitation of photosynthesis hinging on mesophyll conductance (Warren, 2008). This makes mesophyll conductance comparable in magnitude to that of the stomatal conductance, suggesting that mesophyll conductance is one of the most fundamental measurements necessary for developing the predictive capacity of plants’ response to ecosystem changes. Accurate measurements of the mesophyll conductance also lead to better informed models that can upscale assimilation measurements from leaf chambers, by providing quantitative constraints for modeling the uptake of carbonyl sulfide and carbon dioxide by the leaf. Additionally, since mesophyll conductance reacts to environmental variation, it can be used as an indicator for leaf stress. Measurements are taken using the ‘variable J’ technique, involving the use of combined fluorescence measurements and gas exchange data to estimate the ratio of photosynthetic assimilation to differences in CO2 concentration between the intercellular air spaces and the sites of carboxylation.