Affiliation:
1. NASA Langley Research Center Hampton VA USA
2. Science Systems and Applications Inc. Hampton VA USA
Abstract
AbstractInteractions between sea ice and clouds represent a mechanism through which sea ice influences climate. We composite cloud properties for ice‐free, marginal ice zone (MIZ), and ice‐covered surfaces during MIZ crossing events to analyze the cloud property differences between surface types. Restricting the analysis to MIZ crossing events enables the isolation of the sea ice effect on clouds from meteorological factors. We find larger cloud fraction (CF) and total water concentration below ∼1.5 km over ice‐free relative to ice‐covered surfaces during non‐summer months. During summer, the results suggest larger CF and total water concentration over ice‐free surfaces, however differences do not exceed observational uncertainty. Cloud property differences are linked to atmospheric thermodynamic profile differences, namely ice‐free surfaces are warmer, moister, less stable, and have more positive surface turbulent fluxes than ice‐covered surfaces. Ice‐free minus ice‐covered cloud property differences scale with surface temperature differences and are only found in the presence of a surface temperature difference. Our results suggest a 0.02 CF and 0.005 g m−3 total water concentration increase (∼5%) at the level of maximum CF between 2000 and 2021 due to the observed Arctic sea ice decline in fall, corresponding to ∼2 W m−2 increase in the net surface radiative flux. Our results support a positive sea ice‐cloud radiative feedback in fall and winter and a negative sea ice‐cloud radiative feedback in spring. We propose an updated conceptual model where the average surface type influence on cloud properties is mediated by surface temperature differences between ice‐free and ice‐covered surfaces.
Publisher
American Geophysical Union (AGU)
Subject
Space and Planetary Science,Earth and Planetary Sciences (miscellaneous),Atmospheric Science,Geophysics
Cited by
4 articles.
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