Challenging and Improving the Simulation of Mid‐Level Mixed‐Phase Clouds Over the High‐Latitude Southern Ocean

Vignon, Étienne; Alexander, Simon P.; DeMott, Paul J.; Sotiropoulou, Georgia; Gerber, Franziska; Hill, Thomas C. J.; Marchand, Roger; Nenes, Athanasios; Berne, Alexis

doi:10.1029/2020jd033490

Cited by 39 publications

(51 citation statements)

References 97 publications

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“…The cold front associated with this cyclone, as with the previous Mawson cyclone, remained well to the north of the continent (not shown, see Vignon et al. [2021] for further details). Satellite images and thermodynamic data from later times indicate that this cyclone weakened as it propagated south‐eastward toward the coast, with cloud dissipating in a midlevel westerly flow on January 16 (not shown).…”

Section: Resultsmentioning

confidence: 60%

“…Following this characterization of the fine‐scale structure of mixed‐phase clouds and precipitation within cyclones adjacent to the Antarctic, the next step is to simulate these events in high‐resolution models. Although it is likely that models will have difficulty producing and maintaining SLW, we suspect that by appropriately tuning the microphysical schemes using MARCUS observations, we will be able to more accurately reproduce the clouds’ vertical structure, evolution, and phase partitioning (Vignon et al., 2021). Such a path to model improvement of Southern Ocean clouds could be informed by recent analyses of geostationary satellite imagery, which are capable of providing cloud macrophysical properties and information on subcloud phase beneath supercooled liquid cloud tops (e.g., Noh et al., 2019).…”

Section: Discussionmentioning

confidence: 99%

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Mixed‐Phase Clouds and Precipitation in Southern Ocean Cyclones and Cloud Systems Observed Poleward of 64°S by Ship‐Based Cloud Radar and Lidar

et al. 2021

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These clouds remain difficult to model correctly due to the interplay of microphysical and dynamical processes which regulate their formation, maintenance, and decay (Sotiropoulou et al., 2016), and because the scales over which these processes occur are substantially smaller than the resolution of climate and weather prediction models. The observed longevity of MPCs indicates that the removal of ice crystals from the cloud through gravitational sedimentation must be balanced by a continuous source of liquid water. Intracloud processes including updrafts and turbulent mixing, or a continuous supply of new liquid at cloud base, must be sufficient to replenish the liquid water (Korolev & Field, 2008;Rauber & Tokay, 1991). The correct modeling of cloud phase partitioning between ice and liquid water is necessary to match observations of reflected shortwave radiation (

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Section: Resultsmentioning

confidence: 60%

Section: Discussionmentioning

confidence: 99%

Mixed‐Phase Clouds and Precipitation in Southern Ocean Cyclones and Cloud Systems Observed Poleward of 64°S by Ship‐Based Cloud Radar and Lidar

et al. 2021

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“…Good agreement between observations and model output was recently achieved by Vignon et al (2021) in regional model simulations with WRF for the Southern Ocean. They adjusted the Morrison microphysics scheme (Morrison et al, 2005) for reduced heterogeneous nucleation consistent with the INP observations of McCluskey et al (2018) and produced realistic cloud water amounts, while simulations with the unmodified parameterization show a deficit of cloud water.…”

Section: Plain Language Summary Liquid Water Is Common In the Clouds Observed At Mcmurdomentioning

confidence: 85%

Predicting Frigid Mixed‐Phase Clouds for Pristine Coastal Antarctica

et al. 2021

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Supercooled water is common in the clouds near coastal Antarctica and occasionally occurs at temperatures at or below −30°C. Yet the ice physics in most regional and global numerical models will glaciate out these clouds. This presents a challenge for the simulation of highly supercooled clouds that were observed at McMurdo, Antarctica during the Atmospheric Radiation Measurement (ARM) West Antarctic Radiation Experiment (AWARE) project during 2015–2017. The polar optimized version of the Weather Research and Forecasting model (Polar WRF) with the recently developed two‐moment P3 microphysics scheme was used to simulate observed supercooled liquid water cases during March and November 2016. Nudging of the simulations to observed rawinsonde profiles and Antarctic automatic weather station observations provided increased realism and much greater cloud water amounts. Sensitivity tests that adjust the ice physics for extremely low ice nucleating particle (INP) concentrations decrease cloud ice and increases the cloud liquid water closer to observed amounts. In these tests, a liquid layer near cloud top is simulated, in agreement with observations. Accurate representation of INP concentrations appears to be critical for the simulation of coastal Antarctic clouds.

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“…The model is initialized and forced at the lateral boundaries by ERA5 reanalysis data (Hersbach et al, 2020). The parameterizations used are: RRTMG (shortwave and longwave radiation), Kain-Fritsch (KF, convection), a modified version of the Morrison scheme that improves representation of secondary ice production (microphysics, Vignon et al, 2021;Sotiropoulou et al, 2021), and MYNN (boundary layer scheme). The simulation is nudged against ERA5 for wind speeds in zonal and meridional direction in the top 20 levels of the atmosphere.…”

Section: Simulation Setupmentioning

confidence: 99%

Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

Sharma

Gerber

Lehning

2021

Preprint

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Abstract. Accurately simulating snow-cover dynamics and the snow-atmosphere coupling is of major importance for topics as wide-ranging as water resources, natural hazards and climate change impacts with consequences for sea-level rise. We present a new modelling framework for atmospheric flow simulations for cryospheric regions called CRYOWRF. CRYOWRF couples the state-of-the-art and widely used atmospheric model WRF, with the detailed snow-cover model SNOWPACK. CRYOWRF makes it feasible to simulate dynamics of a large number of snow layers governed by grain-scale prognostic variables with online coupling to the atmosphere for multiscale simulations from the synoptic to the turbulent scales. Additionally, a new blowing snow scheme is introduced in CRYOWRF and is discussed in detail. CRYOWRF's technical design goals and model capabilities are described and performance costs are shown to compare favourably with existing land surface schemes. Three case studies showcasing envisaged use-cases for CRYOWRF for polar ice sheets and alpine snowpacks are provided to equip potential users with templates for their research. Finally, the future road-map for CRYOWRF's development and usage is discussed.

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Challenging and Improving the Simulation of Mid‐Level Mixed‐Phase Clouds Over the High‐Latitude Southern Ocean

Cited by 39 publications

References 97 publications

Mixed‐Phase Clouds and Precipitation in Southern Ocean Cyclones and Cloud Systems Observed Poleward of 64°S by Ship‐Based Cloud Radar and Lidar

Mixed‐Phase Clouds and Precipitation in Southern Ocean Cyclones and Cloud Systems Observed Poleward of 64°S by Ship‐Based Cloud Radar and Lidar

Predicting Frigid Mixed‐Phase Clouds for Pristine Coastal Antarctica

Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

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