Formation Process of Particles and Cloud Condensation Nuclei Over the Amazon Rainforest: The Role of Local and Remote New-Particle Formation

WashU Affiliated Authors: Jian Wang (Department of Energy, Environmental and Chemical Engineering, Center for Aerosol Science and Engineering)

Abstract: Understanding the formation processes of particles and cloud condensation nuclei (CCN) in pristine environments is a major challenge in assessing the anthropogenic impacts on climate change. Using a state-of-the-art model that systematically simulates the new-particle formation (NPF) from condensable vapors and multi-scale transport of chemical species, we find that NPF contributes ∼90% of the particle number and ∼80% of the CCN at 0.5% supersaturation (CCN0.5%) in the pristine Amazon boundary layer during the wet season. The corresponding contributions are only ∼30% and ∼20% during the dry season because of prevalent biomass burning. In both seasons, ∼50% of the NPF-induced particles and ∼85% of the NPF-induced CCN0.5% in the boundary layer originate from the long-range transport of new particles formed hundreds to thousands of kilometers away. Moreover, about 50%–65% of the NPF-induced particles and 35%–50% of the NPF-induced CCN0.5% originate from the downward transport of new particles formed aloft.

Citation/DOI: https://doi.org/10.1029/2022GL100940