Publications

Liu, HY; Zhang, B; Moore, RH; Ziemba, LD; Ferrare, RA; Choi, H; Sorooshian, A; Painemal, D; Wang, HL; Shook, MA; Scarino, AJ; Hair, JW; Crosbie, EC; Fenn, MA; Shingler, TJ; Hostetler, CA; Chen, G; Kleb, MM; Luo, G; Yu, FQ; Vaughan, MA; Hu, YX; Diskin, GS; Nowak, JB; Digangi, JP; Choi, Y; Keller, CA; Johnson, MS (2025). Tropospheric aerosols over the western North Atlantic Ocean during the winter and summer deployments of ACTIVATE 2020: life cycle, transport, and distribution. ATMOSPHERIC CHEMISTRY AND PHYSICS, 25(4), 2087-2121.

Abstract
The Aerosol Cloud meTeorology Interactions oVer the western ATlantic Experiment (ACTIVATE) is a NASA mission to characterize aerosol-cloud interactions over the western North Atlantic Ocean (WNAO). Such characterization requires understanding of life cycle, composition, transport pathways, and distribution of aerosols over the WNAO. This study uses the GEOS-Chem model to simulate aerosol distributions and properties that are evaluated against aircraft, ground-based, and satellite observations during the winter and summer field deployments in 2020 of ACTIVATE. Transport in the boundary layer (BL) behind cold fronts was a major mechanism for the North American continental outflow of pollution to the WNAO in winter. Turbulent mixing was the main driver for the upward transport of sea salt within and ventilation out of BL in winter. The BL aerosol composition was dominated by sea salt, which increased in the summer, followed by organics and sulfate. Aircraft in situ aerosol measurements provided useful constraints on wet scavenging in GEOS-Chem. The model generally captured observed features such as continental outflow, land-ocean gradient, and mixing of anthropogenic aerosols with sea salt. Model sensitivity experiments with elevated smoke injection heights to the mid-troposphere (versus within BL) better reproduced observations of smoke aerosols from the western US wildfires over the WNAO in the summer. Model analysis suggests strong hygroscopic growth of sea salt particles and their seeding of marine BL clouds over the WNAO (< 35 degrees N). Future modeling efforts should focus on improving parameterizations for aerosol wet scavenging, implementing realistic smoke injection heights, and applying high-resolution models that better resolve vertical transport.

DOI:
10.5194/acp-25-2087-2025

ISSN:
1680-7324