Four‐Dimensional Quantification of Kelvin‐Helmholtz Instabilities in the Polar Summer Mesosphere Using Volumetric Radar Imaging Article Swipe

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Geology Stratification (seeds) Buoyancy Mesosphere Radar Turbulence Froude number Atmospheric sciences Geophysics Physics Meteorology Mechanics Stratosphere Dormancy Germination Seed dormancy Breakup Computer science Telecommunications Biology Botany

Jorge L. Chau , Juan Miguel Urco , Victor Avsarkisov , Juha Vierinen , Ralph Latteck , Chris Hall , Masaki Tsutsumi ·

YOU? · · 2019 · Open Access · · DOI: https://doi.org/10.1029/2019gl086081 · OA: W2995714430

We present and characterize in time and three spatial dimensions a Kelvin‐Helmholtz Instability (KHI) event from polar mesospheric summer echoes (PMSE) observed with the Middle Atmosphere Alomar Radar System. We use a newly developed radar imaging mode, which observed PMSE intensity and line of sight velocity with high temporal and angular resolution. The identified KHI event occurs in a narrow layer of 2.4 km thickness centered at 85 km altitude, is elongated along north‐south direction, presents separation between billows of 8 km in the east‐west direction, and its billow width is 3 km. The accompanying vertical gradients of the horizontal wind are between 35 and 45 m/s/km and vertical velocities inside the billows are 12 m/s. Based on the estimated Richardson ( 0.25), horizontal Froude ( 0.8), and buoyancy Reynolds ( 2.5 10 ) numbers, the observed event is a KHI that occurs under weak stratification and generates strong turbulence.