TY - JOUR
T1 - Links between atmospheric aerosols and sea state in the Arctic Ocean
AU - Moallemi, Alireza
AU - Alberello, Alberto
AU - Thurnherr, Iris
AU - Li, Guangyu
AU - Kanji, Zamin A.
AU - Bergamasco, Filippo
AU - Pohorsky, Roman
AU - Nelli, Filippo
AU - Toffoli, Alessandro
AU - Schmale, Julia
N1 - Funding information: This work was funded by the EPFL Center for Imaging [3D EarthNavigation, 2022]. This research used samples and data provided by the Arctic Century Expedition, a joint initiative led by the Swiss Polar Institute (SPI), the Antarctic and Arctic Research Institute (AARI) and GEOMAR Helmholtz Centre for Ocean Research Kiel (GEOMAR) and funded by the Swiss Polar Foundation. JS holds the Ingvar Kamprad Chair for Extreme Environments Research. AA acknowledges support from EPSRC [EP/Y02012X/1].
PY - 2024/9/26
Y1 - 2024/9/26
N2 - Sea spray emission is the largest mass flux of aerosols to the atmosphere with important impact on atmospheric radiative transfer. However, large uncertainties still exit in constraining this mass flux and its climate forcing, in particular in the Arctic, where sea ice and relatively low wind speed in summer constitute a significantly different regime compared to the global ocean. Sea state conditions and marine boundary layer stability are also critical variables, but their contribution is often overlooked. Here we present concurrent observations of sea state using a novel stereo camera system, sea spray through coarse mode aerosols, and meteorological variables to determine boundary layer stability in the Barents and Kara Seas during the 2021 Arctic Century Expedition. Our findings reveal that aerosol concentrations were highest over open waters, closely correlating with wave height, followed by wind speed, wave steepness, and wave age. Notably, these correlations were stronger under unstable marine boundary layer conditions, reflecting immediate sea spray generation. By analysing various combinations of sea and atmospheric variables, we identified the wave height Reynolds number as the most effective indicator of atmospheric sea spray concentration, explaining 57% of its variability in unstable conditions. Our study underscores the need to consider sea state, wind, and boundary layer conditions together to accurately estimate atmospheric sea spray concentrations in the Arctic.
AB - Sea spray emission is the largest mass flux of aerosols to the atmosphere with important impact on atmospheric radiative transfer. However, large uncertainties still exit in constraining this mass flux and its climate forcing, in particular in the Arctic, where sea ice and relatively low wind speed in summer constitute a significantly different regime compared to the global ocean. Sea state conditions and marine boundary layer stability are also critical variables, but their contribution is often overlooked. Here we present concurrent observations of sea state using a novel stereo camera system, sea spray through coarse mode aerosols, and meteorological variables to determine boundary layer stability in the Barents and Kara Seas during the 2021 Arctic Century Expedition. Our findings reveal that aerosol concentrations were highest over open waters, closely correlating with wave height, followed by wind speed, wave steepness, and wave age. Notably, these correlations were stronger under unstable marine boundary layer conditions, reflecting immediate sea spray generation. By analysing various combinations of sea and atmospheric variables, we identified the wave height Reynolds number as the most effective indicator of atmospheric sea spray concentration, explaining 57% of its variability in unstable conditions. Our study underscores the need to consider sea state, wind, and boundary layer conditions together to accurately estimate atmospheric sea spray concentrations in the Arctic.
KW - Sea spray aerosols
KW - wave height
KW - Arctic Ocean
KW - stereo imaging
U2 - 10.1016/j.atmosenv.2024.120844
DO - 10.1016/j.atmosenv.2024.120844
M3 - Article
VL - 338
JO - Atmospheric Environment
JF - Atmospheric Environment
SN - 1352-2310
M1 - 120844
ER -