Quantifying deposition pathways of Ozone at a rainforest site (ATTO) in the central Amazon basin

Abstract

<p>Direct eddy covariance flux measurements of O<sub>3</sub> in tropical forests are sparse and deposition velocities of O<sub>3</sub> for tropical forest have large uncertainties in models. Therefore, we measured O<sub>3</sub> fluxes at different heights ( 4 m, 12 m, 46 m and 81 m), which is 2 levels within canopy (below crown layer) and two levels above. At the same levels heat and CO<sub>2</sub> fluxes were measured by eddy covariance to differentiate upper canopy fluxes from understory and soil fluxes and to infer stomatal conductance based on the inverted Penman-Monteith equation. Further measurements include the profiles of O<sub>3</sub>, NO<sub>x</sub>, CO<sub>2</sub> and H<sub>2</sub>O which are used to calculate storage fluxes and reactions of O<sub>3</sub> with NO<sub>x</sub> within the air volume. Additionally, leaf surface temperature and leaf wetness were measured in the upper canopy (26 m) to infer their influence on the non-stomatal deposition. The measurements took place at the ATTO (Amazon Tall Tower Observatory) site that is located about 150 km northeast of the city of Manaus in the Amazon rainforest. (02°08’38.8’’S, 58°59’59.5’’W). The climate in this region is characterized by a rainy (350 mm around March) and a dry season (ca. 80 mm in September). During the wet months, the air quality is close to pristine, while strong pollution from biomass burning is evident in the dry season. Therefore, we will present results from two intensive campaigns (3- 4 flux levels) for the rainy season (March to May) and the dry season (September to December) 2018.</p><p> </p><p>The focus of the analysis is the partitioning between a) the crown layer and understory and b) stomatal and non-stomatal deposition with a further analysis of the non-stomatal pathways. Non-stomatal deposition is analyzed by quantifying gas-phase reactions of O<sub>3</sub> with NO<sub>x</sub> and an estimate of O<sub>3</sub> reactivity by VOCs. Furthermore, the remaining (surface) deposition is analyzed according to its relations with leaf surface temperature and leaf wetness.</p>