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1. Impacts of Limited Model Resolution on the Representation of Mountain Wave and Secondary Wave Dynamics in Local and Global Models: 2. Mountain Wave and Secondary Wave Evolutions in the Thermosphere

   https://doi.org/10.1029/2021JD036035  

   Fritts, David C.; Lund, Adam C.; Lund, Thomas S.; Yudin, Valery (May 2022, Journal of Geophysical Research: Atmospheres)
2. Numerical Simulation of Mountain Waves over the Southern Andes. Part I: Mountain Wave and Secondary Wave Character, Evolutions, and Breaking

   https://doi.org/10.1175/JAS-D-19-0356.1  

   Lund, Thomas S.; Fritts, David C.; Wan, Kam; Laughman, Brian; Liu, Han-Li (December 2020, Journal of the Atmospheric Sciences)

   null (Ed.)

   Abstract This paper addresses the compressible nonlinear dynamics accompanying increasing mountain wave (MW) forcing over the southern Andes and propagation into the mesosphere and lower thermosphere (MLT) under winter conditions. A stretched grid provides very high resolution of the MW dynamics in a large computational domain. A slow increase of cross-mountain winds enables MWs to initially break in the mesosphere and extend to lower and higher altitudes thereafter. MW structure and breaking is strongly modulated by static mean and semidiurnal tide fields exhibiting a critical level at ~114 km for zonal MW propagation. Varying vertical group velocities for different zonal wavelengths λ x yield initial breaking in the lee of the major Andes peaks for λ x ~ 50 km, and extending significantly upstream for larger λ x approaching the critical level at later times. The localized extent of the Andes terrain in latitude leads to “ship wave” responses above the individual peaks at earlier times, and a much larger ship-wave response at 100 km and above as the larger-scale MWs achieve large amplitudes. Other responses above regions of MW breaking include large-scale secondary gravity waves and acoustic waves that achieve very large amplitudes extending well into the thermosphere. MW breaking also causes momentum deposition that yields local decelerations initially, which merge and extend horizontally thereafter and persist throughout the event. Companion papers examine the associated momentum fluxes, mean-flow evolution, gravity wave–tidal interactions, and the MW instability dynamics and sources of secondary gravity waves and acoustic waves. 

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3. Mesospheric Mountain Wave Activity in the Lee of the Southern Andes

   https://doi.org/10.1029/2020JD033268  

   Pautet, P.‐D.; Taylor, M. J.; Fritts, D. C.; Janches, D.; Kaifler, N.; Dörnbrack, A.; Hormaechea, J. L. (April 2021, Journal of Geophysical Research: Atmospheres)

   null (Ed.)
4. 3D Numerical Simulation of Secondary Wave Generation From Mountain Wave Breaking Over Europe

   https://doi.org/10.1029/2021JD035413  

   Heale, Christopher J.; Bossert, Katrina; Vadas, Sharon L. (March 2022, Journal of Geophysical Research: Atmospheres)
5. The Influence of Vertical Wind Shear on the Evolution of Mountain-Wave Momentum Flux

   https://doi.org/10.1175/JAS-D-18-0231.1  

   Durran, Dale R.; Menchaca, Maximo Q. (March 2019, Journal of the Atmospheric Sciences)

   null (Ed.)

   Abstract The influence of vertical shear on the evolution of mountain-wave momentum fluxes in time-varying cross-mountain flows is investigated by numerical simulation and analyzed using ray tracing and the WKB approximation. The previously documented tendency of momentum fluxes to be strongest during periods of large-scale cross-mountain flow acceleration can be eliminated when the cross-mountain wind increases strongly with height. In particular, the wave packet accumulation mechanism responsible for the enhancement of the momentum flux during periods of cross-mountain flow acceleration is eliminated by the tendency of the vertical group velocity to increase with height in a mean flow with strong forward shear, thereby promoting vertical separation rather than concentration of vertically propagating wave packets. 

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