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Secondary Gravity Waves From the Stratospheric Polar Vortex Over ALOMAR Observatory on 12–14 January 2016: Observations and Modeling

Sharon L. Vadas, Erich Becker, Katrina Bossert, Gerd Baumgarten, Lars Hoffmann, V. Lynn Harvey

2023Journal of Geophysical Research Atmospheres30 citationsDOIOpen Access PDF

Abstract

Abstract We analyze the gravity waves (GWs) observed by a Rayleigh lidar at the Arctic Lidar Observatory for Middle Atmosphere Research (ALOMAR) (16.08°E, 69.38°N) in Norway at z ∼ 20–85 km on 12–14 January 2016. These GWs propagate upward and downward away from z knee = 57 and 64 km at a horizontally‐displaced location with periods τ r ∼ 5–10 hr and vertical wavelengths λ z ∼ 9–20 km. Because the hodographs are distorted, we introduce an alternative method to determine the GW parameters. We find that these GWs are medium to large‐scale, and propagate north/northwestward with intrinsic horizontal phase speeds of ∼35–65 m/s. Since the GW parameters are similar above and below z knee , these are secondary GWs created by local body forces (LBFs) south/southeast of ALOMAR. We use the nudged HIAMCM (HIgh Altitude Mechanistic general Circulation Model) to model these events. Remarkably, the model reproduces similar GW structures over ALOMAR, with z knee = 58 and 66 km. The event #1 GWs are created by a LBF at ∼35°E, ∼60°N, and z ∼ 58 km. This LBF is created by the breaking and dissipation of primary GWs generated and amplified by the imbalance of the polar night jet below the wind maximum; the primary GWs for this event are created at z ∼ 25–35 km at 49–53°N. We also find that the HIAMCM GWs agree well with those observed by the Atmospheric InfraRed Sounder (AIRS) satellite, and that those AIRS GWs south and north of ∼50°N over Europe are mainly mountain waves and GWs from the polar vortex, respectively.

Topics & Concepts

ObservatoryGravitational wavePhysicsLidarGravity waveGeologySatelliteGeodesyAtmospheric sciencesAstrophysicsAstronomyRemote sensingIonosphere and magnetosphere dynamicsMeteorological Phenomena and SimulationsAtmospheric Ozone and Climate