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- Title
Enhancements in Cloud Condensation Nuclei Activity From Turbulent Fluctuations in Supersaturation.
- Authors
Anderson, Jesse C.; Beeler, Payton; Ovchinnikov, Mikhail; Cantrell, Will; Krueger, Steven; Shaw, Raymond A.; Yang, Fan; Fierce, Laura
- Abstract
The effect of aerosols on the properties of clouds is a large source of uncertainty in predictions of weather and climate. These aerosol‐cloud interactions depend critically on the ability of aerosol particles to form cloud droplets. A challenge in modeling aerosol‐cloud interactions is the representation of interactions between turbulence and cloud microphysics. Turbulent mixing leads to small‐scale fluctuations in water vapor and temperature that are unresolved in large‐scale atmospheric models. To quantify the impact of turbulent fluctuations on cloud condensation nuclei (CCN) activation, we used a high‐resolution Large Eddy Simulation of a convective cloud chamber to drive particle‐based cloud microphysics simulations. We show small‐scale fluctuations strongly impact CCN activity. Once activated, the relatively long timescales of evaporation compared to fluctuations causes droplets to persist in subsaturated regions, which further increases droplet concentrations. Plain Language Summary: Increases in cloud droplet number concentrations from human emissions of aerosol particles modify cloud properties, which strongly impacts Earth's energy balance. Large Eddy Simulations and Earth System Models are used to quantify these aerosol‐cloud interactions, but the spatial and temporal resolution of these models is too coarse to represent the impact of turbulence at the smallest scales. In this study, we show that small‐scale turbulent fluctuations lead to cloud droplet formation even when air is, on average, subsaturated, which would be impossible in conventional models of cloud microphysics. Our findings suggest that models that neglect turbulent fluctuations in supersaturation will underestimate cloud condensation nuclei activity under specific supersaturation regimes, which will may lead to error in modeled cloud properties. Key Points: Small‐scale turbulence leads to variability in the supersaturation experienced by aerosol particles and cloud droplets within cloudsTurbulent fluctuations increase cloud droplet formation at low supersaturation levels in comparison with uniform environmental conditionsAtmospheric models that neglect supersaturation variability due to turbulence may underestimate the number concentration of cloud droplets
- Subjects
CLOUD condensation nuclei; SUPERSATURATION; CLOUD droplets; LARGE eddy simulation models; TURBULENT mixing
- Publication
Geophysical Research Letters, 2023, Vol 50, Issue 17, p1
- ISSN
0094-8276
- Publication type
Article
- DOI
10.1029/2022GL102635