Abstract
<strong class="journal-contentHeaderColor">Abstract.</strong> In January 2020, unexpected easterly winds developed in the downward-propagating westerly quasi-biennial oscillation (QBO) phase. This event corresponds to the second QBO disruption in history, and it occurred 4Â years after the first disruption of 2015/16. According to several previous studies, strong midlatitude Rossby waves propagating from the Southern Hemisphere (SH) during the SH winter likely initiated the disruption; nevertheless, the wave forcing that finally led to the disruption has not been investigated. In this study, we examine the role of equatorial waves and small-scale convective gravity waves (CGWs) in the 2019/20 QBO disruption using Modern-Era Retrospective Analysis for Research and Applications version 2 (MERRA-2) global reanalysis data. In JuneâSeptember 2019, unusually strong Rossby wave forcing originating from the SH decelerated the westerly QBO at 0â5<span class="inline-formula"><sup>â</sup></span>âN at <span class="inline-formula">â¼50</span>âhPa. In OctoberâNovember 2019, vertically (horizontally) propagating Rossby waves and mixed Rossbyâgravity (MRG) waves began to increase (decrease). From December 2019, the contribution of the MRG wave forcing to the zonal wind deceleration was the largest, followed by the Rossby wave forcing originating from the Northern Hemisphere and the equatorial troposphere. In January 2020, CGWs provided 11â% of the total negative wave forcing at <span class="inline-formula">â¼43</span>âhPa. Inertiaâgravity (IG) waves exhibited a moderate contribution to the negative forcing throughout. Although the zonal mean precipitation was not significantly larger than the climatology, convectively coupled equatorial wave activities were increased during the 2019/20 disruption. As in the 2015/16 QBO disruption, the increased barotropic instability at the QBO edges generated more MRG waves at 70â90âhPa, and westerly anomalies in the upper troposphere allowed more westward IG waves and CGWs to propagate to the stratosphere. Combining the 2015/16 and 2019/20 disruption cases, Rossby waves and MRG waves can be considered the key factors inducing QBO disruption.
Highlights
The quasi-biennial oscillation (QBO) was first recorded through radiosonde wind observations in 1953 (Naujokat, 25 1986)
We examine the role of equatorial waves and small-scale convective gravity waves (CGWs) in the 2019/20 QBO disruption using MERRA-2 global reanalysis data
We provide a comprehensive overview of the 2019/20 QBO disruption by examining all the equatorial waves (Kelvin, Rossby, mixed Rossby–gravity (MRG), and IG waves) and small-scale CGWs as in KCG20
Summary
The quasi-biennial oscillation (QBO) was first recorded through radiosonde wind observations in 1953 (Naujokat, 25 1986). A QBO phase transition has been made regularly by the descent of the opposite QBO phase with periods of 20–35 months. In February 2016, easterly forcing in the middle of the westerly winds disrupted the downwardpropagating westerly QBO for the first time (Osprey et al, 2016), which is referred to as the 2015/16 QBO disruption. Discussion started: 1 March 2021 c Author(s) 2021.
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