Characterizing Ice Nucleating Particles over the Southern Ocean using Simultaneous Aircraft and Ship Observations

Supercooled liquid clouds are ubiquitous over the Southern Ocean (SO), even to temperatures below -20 °C, and comprise a large fraction of the marine boundary layer (MBL) clouds. Earth system models and reanalysis products have struggled to reproduce the observed cloud phase distribution and occurre...

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Bibliographic Details
Main Authors: Moore, Kathryn A, Hill, Thomas C. J., McCluskey, Christina S., Twohy, Cynthia H., Rainwater, Bryan, Toohey, Darin W., Sanchez, Kevin, Kreidenweis, Sonia M., DeMott, Paul J
Format: Other/Unknown Material
Language:unknown
Published: Authorea, Inc. 2023
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Online Access:http://dx.doi.org/10.22541/essoar.168889890.00880378/v1
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Summary:Supercooled liquid clouds are ubiquitous over the Southern Ocean (SO), even to temperatures below -20 °C, and comprise a large fraction of the marine boundary layer (MBL) clouds. Earth system models and reanalysis products have struggled to reproduce the observed cloud phase distribution and occurrence of cloud ice in the region. Recent simulations found the microphysical representation of ice nucleation and growth has a large impact on these properties, however, measurements of SO ice nucleating particles (INPs) to validate simulations are sparse. This study presents measurements of INPs from simultaneous aircraft and ship campaigns conducted over the SO in austral summer 2018, which include the first in situ observations in and above cloud in the region. Our results confirm recent observations that INP concentrations are uniformly lower than measurements made in the late 1960s. While INP concentrations below and above cloud are similar, higher ice nucleation efficiency above cloud supports model inferences that the dominant INP composition varies with height. Model parameterizations based solely on aerosol properties capture the mean relationship between INP concentration and temperature but not the observed variability, which is likely related to the only modest correlations observed between INPs and environmental or aerosol metrics. An updated parameterization for marine INPs is proposed, which reduces bias relative to existing methods by including wind speed as an additional variable. Direct and indirect inference of marine INP size suggests MBL INPs, at least those in the sub-2.5 μm range, are dominated by particles with diameters smaller than 500 nm.