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Quasi‐10‐Day Wave and Semidiurnal Tide Nonlinear Interactions During the Southern Hemispheric SSW 2019 Observed in the Northern Hemispheric Mesosphere

Maosheng He, Jorge L. Chau, J. M. Forbes, Denise Thorsen, Guozhu Li, Tarique Adnan Siddiqui, Yosuke Yamazaki, W. K. Hocking

2020Geophysical Research Letters36 citationsDOIOpen Access PDF

Abstract

Abstract Mesospheric winds from three longitudinal sectors at 65°N and 54°N latitude are combined to diagnose the zonal wave numbers ( m ) of spectral wave signatures during the Southern Hemisphere sudden stratospheric warming (SSW) 2019. Diagnosed are quasi‐10‐ and 6‐day planetary waves (Q10DW and Q6DW, m = 1), solar semidiurnal tides with m = 1, 2, 3 (SW1, SW2, and SW3), lunar semidiurnal tide, and the upper and lower sidebands (USB and LSB, m = 1 and 3) of Q10DW‐SW2 nonlinear interactions. We further present 7‐year composite analyses to distinguish SSW effects from climatological features. Before (after) the SSW onset, LSB (USB) enhances, accompanied by the enhancing (fading) Q10DW, and a weakening of climatological SW2 maximum. These behaviors are explained in terms of Manley‐Rowe relation, that is, the energy goes first from SW2 to Q10DW and LSB, and then from SW2 and Q10DW to USB. Our results illustrate that the interactions can explain most wind variabilities associated with the SSW.

Topics & Concepts

MesosphereNorthern HemisphereAtmospheric sciencesGeologyStratopauseSouthern HemisphereGravity waveSudden stratospheric warmingPhysicsClimatologyStratosphereGeophysicsAstrophysicsPolar vortexGravitational waveAtmospheric Ozone and ClimateIonosphere and magnetosphere dynamicsSolar and Space Plasma Dynamics