Stratospheric ozone and quasi-biennial oscillation (QBO) interaction with the tropical troposphere on intraseasonal and interannual timescales: a normal-mode perspective

Earth System Dynamics Discussions Pub Date : 2021-01-18 DOI:10.5194/ESD-12-83-2021

B. Raphaldini, Andre S. W. Teruya, Pedro Leite da Silva Dias, L. Massaroppe, D. Y. Takahashi

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引用次数: 7

Abstract

Abstract. The Madden–Julian oscillation (MJO) is the main controller of the weather in the tropics on intraseasonal timescales, and recent research provides evidence that the quasi-biennial oscillation (QBO) influences the MJO interannual variability. However, the physical mechanisms behind this interaction are not completely understood. Recent studies on the normal-mode structure of the MJO indicate the contribution of global-scale Kelvin and Rossby waves. In this study we test whether these MJO-related normal modes are affected by the QBO and stratospheric ozone. The partial directed coherence method was used and enabled us to probe the direction and frequency of the interactions. It was found that equatorial stratospheric ozone and stratospheric zonal winds are connected with the MJO at periods of 1–2 months and 1.5–2.5 years. We explore the role of normal-mode interactions behind the stratosphere–troposphere coupling by performing a linear regression between the MJO–QBO indices and the amplitudes of the normal modes of the atmosphere obtained by projections on a normal-mode basis using ERA-Interim reanalysis data. The MJO is dominated by symmetric Rossby modes but is also influenced by Kelvin and asymmetric Rossby modes. The QBO is mostly explained by westward-propagating inertio-gravity waves and asymmetric Rossby waves. We explore the previous results by identifying interactions between those modes and between the modes and the ozone concentration. In particular, westward inertio-gravity waves, associated with the QBO, influence the MJO on interannual timescales. MJO-related modes, such as Kelvin waves and Rossby waves with a symmetric wind structure with respect to the Equator, are shown to have significantly different dynamics during MJO events depending on the phase of the QBO.

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平流层臭氧和准两年生振荡(QBO)与热带对流层在季节内和年际时间尺度上的相互作用:正态模态视角

摘要麦登-朱利安涛动(Madden-Julian oscillation, MJO)是热带地区季节内气候变化的主要控制因子，近年来的研究表明，准二年生涛动(QBO)影响着MJO的年际变化。然而，这种相互作用背后的物理机制尚不完全清楚。最近对MJO正模态结构的研究表明全球尺度开尔文安德洛斯比波的贡献。在本研究中，我们检验了这些与mjo相关的正常模态是否受到QBO和平流层臭氧的影响。使用部分定向相干方法，我们可以探测到相互作用的方向和频率。发现赤道平流层臭氧和平流层纬向风与MJO的关联周期为1 ~ 2个月和1.5 ~ 2.5年。我们通过使用ERA-Interim再分析数据在正模基础上预估得到的MJO-QBO指数和大气正模振幅之间的线性回归，探讨了平流层-对流层耦合背后的正模相互作用的作用。MJO以对称罗斯比模为主，但也受开尔文模和非对称罗斯比模的影响。QBO主要由向西传播的惯性重力波和不对称罗斯比波来解释。我们通过确定这些模态之间以及模态与臭氧浓度之间的相互作用来探索以前的结果。特别是，与QBO相关的西向惯性重力波在年际时间尺度上影响MJO。与MJO相关的模态，如相对于赤道具有对称风结构的开尔文波和罗斯比波，在MJO事件期间具有显著不同的动力学，这取决于QBO的相位。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Earth System Dynamics Discussions

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