TY - JOUR
T1 - Multilayer Observations and Modeling of Thunderstorm-Generated Gravity Waves Over the Midwestern United States
AU - Heale, C. J.
AU - Snively, J. B.
AU - Bhatt, A. N.
AU - Hoffmann, L.
AU - Stephan, C. C.
N1 - Heale, C. J., Snively, J. B., Bhatt, A. N.,
Hoffmann, L., Stephan, C. C.,
Kendall, E. A. (2019). Multilayer
observations and modeling of
thunderstorm-generated gravity waves
over the Midwestern United States.
Geophysical Research Letters, 46,
14,164–14,174. https://doi.org/10.
1029/2019GL085934
PY - 2019/12/3
Y1 - 2019/12/3
N2 - We present multilayer observations and numerical simulations of gravity waves (GWs) generated by a series of Mesoscale Convective Systems over the midwestern United States. Strong semiconcentric GWs were observed and modeled, which couple from their tropospheric sources to the thermosphere, displaying strong nonlinearity indicated by instability, breaking, and formation of turbulent vortices. GWs in the stratosphere display a large range of horizontal scales from 34–400 km; however, the smaller wavelength waves break rapidly in the mesosphere and lower thermosphere. Larger-scale (≥150 km) waves dominate in the thermosphere and display northwestward propagation at 200–300 km altitude, opposing the mean winds. Despite strong molecular viscosity and thermal conductivity in the thermosphere, steepened wave fronts, which may indicate nonlinearity, is identified in 630 nm airglow imagers. The agreement between model and data suggests new opportunities for data-constrained simulations that span multilayer observables, including mesosphere and lower thermosphere-region airglow not captured for this event.
AB - We present multilayer observations and numerical simulations of gravity waves (GWs) generated by a series of Mesoscale Convective Systems over the midwestern United States. Strong semiconcentric GWs were observed and modeled, which couple from their tropospheric sources to the thermosphere, displaying strong nonlinearity indicated by instability, breaking, and formation of turbulent vortices. GWs in the stratosphere display a large range of horizontal scales from 34–400 km; however, the smaller wavelength waves break rapidly in the mesosphere and lower thermosphere. Larger-scale (≥150 km) waves dominate in the thermosphere and display northwestward propagation at 200–300 km altitude, opposing the mean winds. Despite strong molecular viscosity and thermal conductivity in the thermosphere, steepened wave fronts, which may indicate nonlinearity, is identified in 630 nm airglow imagers. The agreement between model and data suggests new opportunities for data-constrained simulations that span multilayer observables, including mesosphere and lower thermosphere-region airglow not captured for this event.
KW - acoustic-gravity waves
KW - large eddy simulation
KW - thermospheric dynamics
KW - multilayer coupling
KW - multilayer observation
KW - convective wave generation
UR - https://commons.erau.edu/publication/1813
U2 - 10.1029/2019GL085934
DO - 10.1029/2019GL085934
M3 - Article
VL - 46
JO - Geophysical Research Letters
JF - Geophysical Research Letters
ER -