TY - JOUR
T1 - Secondary Gravity Waves From the Stratospheric Polar Vortex Over ALOMAR Observatory on 12–14 January 2016
T2 - Observations and Modeling
AU - Vadas, Sharon L.
AU - Becker, Erich
AU - Bossert, Katrina
AU - Baumgarten, Gerd
AU - Hoffmann, Lars
AU - Harvey, V. Lynn
N1 - Funding Information: We would like to thank Dr. Xinzhao Chu and two anonymous reviewers for helpful comments. SLV was supported by NSF Grants AGS-1822867 and AGS-1832988. SLV and EB were supported by DARPA contract 140D6319C0032, and NASA Grants 80NSSC20K0628 and 80NSSC19K0836. The model data shown in this paper will be available via NWRA's website at https://www.cora.nwra.com/vadas/Vadas_etal_January2016-JGR_2022_files/ once this paper is published. EB was additionally supported by the Leibniz Institute of Atmospheric Physics at the University of Rostock (IAP), which provided the HPC facility used for this study. KB was supported by NSF grant AGS-2052993 and NASA Grant 80NSSC19K0836. GB acknowledges the contribution of the project W1 (Gravity wave parameterizations for the atmosphere) of the Collaborative Research Centre TRR 181 “Energy Transfers in Atmosphere and Ocean” funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under project number 274762653. LH acknowledges the Juehlich Supercomputing Centre for providing computing time on the JUWELS cluster to process the AIRS high-resolution temperature retrievals. VLH acknowledges NASA Grant 80NSSC19K0834. The views, opinions and/or findings expressed are those of the author and should not be interpreted as representing the official views or policies of the Department of Defense or the U.S. Government. Funding Information: We would like to thank Dr. Xinzhao Chu and two anonymous reviewers for helpful comments. SLV was supported by NSF Grants AGS‐1822867 and AGS‐1832988. SLV and EB were supported by DARPA contract 140D6319C0032, and NASA Grants 80NSSC20K0628 and 80NSSC19K0836. The model data shown in this paper will be available via NWRA's website at https://www.cora.nwra.com/vadas/Vadas_etal_January2016-JGR_2022_files/ once this paper is published. EB was additionally supported by the Leibniz Institute of Atmospheric Physics at the University of Rostock (IAP), which provided the HPC facility used for this study. KB was supported by NSF grant AGS‐2052993 and NASA Grant 80NSSC19K0836. GB acknowledges the contribution of the project W1 (Gravity wave parameterizations for the atmosphere) of the Collaborative Research Centre TRR 181 “Energy Transfers in Atmosphere and Ocean” funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under project number 274762653. LH acknowledges the Juehlich Supercomputing Centre for providing computing time on the JUWELS cluster to process the AIRS high‐resolution temperature retrievals. VLH acknowledges NASA Grant 80NSSC19K0834. The views, opinions and/or findings expressed are those of the author and should not be interpreted as representing the official views or policies of the Department of Defense or the U.S. Government. Publisher Copyright: © 2023. American Geophysical Union. All Rights Reserved.
PY - 2023/1/27
Y1 - 2023/1/27
N2 - 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 zknee = 57 and 64 km at a horizontally-displaced location with periods τr ∼ 5–10 hr and vertical wavelengths λz ∼ 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 zknee, 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 zknee = 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.
AB - 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 zknee = 57 and 64 km at a horizontally-displaced location with periods τr ∼ 5–10 hr and vertical wavelengths λz ∼ 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 zknee, 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 zknee = 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.
KW - AIRS observations
KW - lidar observations
KW - mountain waves
KW - polar vortex
KW - secondary gravity waves
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U2 - https://doi.org/10.1029/2022JD036985
DO - https://doi.org/10.1029/2022JD036985
M3 - Article
SN - 2169-897X
VL - 128
JO - Journal of Geophysical Research: Atmospheres
JF - Journal of Geophysical Research: Atmospheres
IS - 2
M1 - e2022JD036985
ER -