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A Polarimetric Radar Analysis of Ice Microphysical Processes in Melting Layers of Winter Storms Using S-Band Quasi-Vertical Profiles

Erica M. Griffin, Terry J. Schuur, Alexander V. Ryzhkov

2020Journal of Applied Meteorology and Climatology33 citationsDOIOpen Access PDF

Abstract

Abstract Quasi-vertical profiles (QVPs) obtained from a database of U.S. WSR-88D data are used to document polarimetric characteristics of the melting layer (ML) in cold-season storms with high vertical resolution and accuracy. A polarimetric technique to define the top and bottom of the ML is first introduced. Using the QVPs, statistical relationships are developed to gain insight into the evolution of microphysical processes above, within, and below the ML, leading to a statistical polarimetric model of the ML that reveals characteristics that reflectivity data alone are not able to provide, particularly in regions of weak reflectivity factor at horizontal polarization Z H . QVP ML statistics are examined for two regimes in the ML data: Z H ≥ 20 dB Z and Z H < 20 dB Z . Regions of Z H ≥ 20 dB Z indicate locations of MLs collocated with enhanced differential reflectivity Z DR and reduced copolar correlation coefficient ρ hv , while for Z H < 20 dB Z a well-defined ML is difficult to discern using Z H alone. Evidence of large Z DR up to 4 dB, backscatter differential phase δ up to 8°, and low ρ hv down to 0.80 associated with lower Z H (from −10 to 20 dB Z ) in the ML is observed when pristine, nonaggregated ice falls through it. Positive correlation is documented between maximum specific differential phase K DP and maximum Z H in the ML; these are the first QVP observations of K DP in MLs documented at S band. Negative correlation occurs between minimum ρ hv in the ML and ML depth and between minimum ρ hv in the ML and the corresponding enhancement of Z H (Δ Z H = Z H max − Z H rain ).

Topics & Concepts

Differential phasePolarimetryCorrelation coefficientBackscatter (email)RadarPhysicsPolarization (electrochemistry)StormWinter stormReflectivityAtmospheric sciencesEnvironmental scienceMeteorologyComputational physicsGeologyRemote sensingPhase (matter)OpticsScatteringMathematicsChemistryStatisticsQuantum mechanicsTelecommunicationsWirelessComputer sciencePhysical chemistryPrecipitation Measurement and AnalysisMeteorological Phenomena and SimulationsCryospheric studies and observations
A Polarimetric Radar Analysis of Ice Microphysical Processes in Melting Layers of Winter Storms Using S-Band Quasi-Vertical Profiles | Litcius