TY - JOUR
T1 - Characteristics of the Quiet-Time Hot Spot Gravity Waves Observed by GOCE Over the Southern Andes on 5 July 2010
AU - Vadas, Sharon L.
AU - Xu, Shuang
AU - Yue, Jia
AU - Bossert, Katrina
AU - Becker, Erich
AU - Baumgarten, Gerd
N1 - Funding Information:
S. L. V. was supported by NSF grants AGS-1832988, AGS-1552315, AGS-1452329, and AGS-1242897. J. Y. was supported by NSF grants AGS-1651394 and AGS-1834222, and NASA's Small Explorers Program AIM under contract NAS5-03132. K. B. was supported by NSF grant AGS-1822585. E. B. was supported by the Collaborative Research Centre TRR 181 (subproject T1) funded by the German Research Foundation. Data from MERRA-2 is available online (https://gmao.gsfc.nasa.gov/reanalysis/MERRA-2/). Data from MSIS is available online (https://ccmc.gsfc.nasa.gov/modelweb/models/nrlmsise00.php). Data from HWM is available in “Supporting Information” of Drob et al. (; https://agupubs.onlinelibrary.wiley.com/doi/10.1002/2014EA000089). The GOCE data access is https://earth.esa.int/web/guest/-/goce-data-access-7219, and the direct download link for GOCE data is http://eo-virtual-archive1.esa.int/GOCE-Thermosphere.html; data from AIRS and MERRA-2 are available online (https://disc.gsfc.nasa.gov/SSW/#keywords=), and data from SABER are available online (http://saber.gats-inc.com/data.php). The model data shown in this paper are available via NWRA's website (https://www.cora.nwra.com/vadas/Vadas_etal_GOCEJGR_2019_files/).
Publisher Copyright:
©2019. The Authors.
PY - 2019/8/1
Y1 - 2019/8/1
N2 - We analyze quiet-time data from the Gravity Field and Ocean Circulation Explorer satellite as it overpassed the Southern Andes at z≃275 km on 5 July 2010 at 23 UT. We extract the 20 largest traveling atmospheric disturbances from the density perturbations and cross-track winds using Fourier analysis. Using gravity wave (GW) dissipative theory that includes realistic molecular viscosity, we search parameter space to determine which hot spot traveling atmospheric disturbances are GWs. This results in the identification of 17 GWs having horizontal wavelengths λH = 170–1,850 km, intrinsic periods τIr = 11–54 min, intrinsic horizontal phase speeds cIH = 245–630 m/s, and density perturbations (Formula presented.) 0.03–7%. We unambiguously determine the propagation direction for 11 of these GWs and find that most had large meridional components to their propagation directions. Using reverse ray tracing, we find that 10 of these GWs must have been created in the mesosphere or thermosphere. We show that mountain waves (MWs) were observed in the stratosphere earlier that day and that these MWs saturated at z∼ 70–75 km from convective instability. We suggest that these 10 Gravity Field and Ocean Circulation Explorer hot spot GWs are likely tertiary (or higher-order) GWs created from the dissipation of secondary GWs excited by the local body forces created from MW breaking. We suggest that the other GW is likely a secondary or tertiary (or higher-order) GW. This study strongly suggests that the hot spot GWs over the Southern Andes in the quiet-time middle winter thermosphere cannot be successfully modeled by conventional global circulation models where GWs are parameterized and launched in the troposphere or stratosphere.
AB - We analyze quiet-time data from the Gravity Field and Ocean Circulation Explorer satellite as it overpassed the Southern Andes at z≃275 km on 5 July 2010 at 23 UT. We extract the 20 largest traveling atmospheric disturbances from the density perturbations and cross-track winds using Fourier analysis. Using gravity wave (GW) dissipative theory that includes realistic molecular viscosity, we search parameter space to determine which hot spot traveling atmospheric disturbances are GWs. This results in the identification of 17 GWs having horizontal wavelengths λH = 170–1,850 km, intrinsic periods τIr = 11–54 min, intrinsic horizontal phase speeds cIH = 245–630 m/s, and density perturbations (Formula presented.) 0.03–7%. We unambiguously determine the propagation direction for 11 of these GWs and find that most had large meridional components to their propagation directions. Using reverse ray tracing, we find that 10 of these GWs must have been created in the mesosphere or thermosphere. We show that mountain waves (MWs) were observed in the stratosphere earlier that day and that these MWs saturated at z∼ 70–75 km from convective instability. We suggest that these 10 Gravity Field and Ocean Circulation Explorer hot spot GWs are likely tertiary (or higher-order) GWs created from the dissipation of secondary GWs excited by the local body forces created from MW breaking. We suggest that the other GW is likely a secondary or tertiary (or higher-order) GW. This study strongly suggests that the hot spot GWs over the Southern Andes in the quiet-time middle winter thermosphere cannot be successfully modeled by conventional global circulation models where GWs are parameterized and launched in the troposphere or stratosphere.
KW - gravity waves
KW - mountain waves
KW - secondary gravity waves
KW - tertiary gravity waves
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U2 - 10.1029/2019JA026693
DO - 10.1029/2019JA026693
M3 - Article
AN - SCOPUS:85070761693
SN - 2169-9380
VL - 124
SP - 7034
EP - 7061
JO - Journal of Geophysical Research A: Space Physics
JF - Journal of Geophysical Research A: Space Physics
IS - 8
ER -