当前和未来全球变暖背景下ENSO遥相关的综述

Omid Alizadeh
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引用次数: 1

摘要

厄尔Niño -南方涛动(ENSO)是地球气候的一个主要组成部分,它通过远距离遥相关在很大程度上影响全球气候变率。热带对流产生的罗斯比波列及其向温带地区的传播是热带和温带遥相关的关键机制。尽管在过去的几十年里,对ENSO远程连接的理解取得了重大进展,但仍有几个重要问题有待解决。ENSO的全球大气遥相关在季节周期、年代际尺度和全球变暖的影响下变化很大。必须将ENSO遥相关的内部年代际变率与全球变暖的外部强迫引起的变化区分开来。然而,卫星后观测的时间还不够长,无法形成大量的ENSO事件来区分ENSO遥相关的年代际变率与温室浓度增加相关的变化。目前的气候模式也存在普遍的偏差,因此它们不能正确地再现热带平均状态和ENSO的某些特征。然而,观测记录可以通过重建方法延长时间。人们也已经在努力消除气候模式的一些主要的共同偏差,并改进ENSO特征的表现。这些可靠的重建数据以及改进气候模式模拟的大量集合成员可以应用于加深我们对ENSO全球遥相关及其对内部年代际变率和外部强迫全球变暖的响应的理解。本文分类如下:古气候和当前趋势;现代气候变化气候模式与模拟>评估气候变化影响的地球系统模型评估未来气候变化的影响
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A review of ENSO teleconnections at present and under future global warming
Abstract The El Niño‐Southern Oscillation (ENSO) is a major component of the Earth's climate that largely influences global climate variability through long‐distance teleconnections. Rossby wave trains emerging from the tropical convection and their propagation into extratropical regions are the key mechanism for tropical and extratropical teleconnections. Despite significant progress in the understanding of ENSO teleconnections over the recent past decades, several important issues have remained to be addressed. The global atmospheric teleconnections of ENSO vary substantially with the seasonal cycle, on the decadal timescale, and under the influence of global warming. It is essential to separate the internal decadal variability of ENSO teleconnections from changes caused by the external forcing of global warming. However, the post‐satellite observations are not long enough to compose a large number of ENSO events to distinguish the decadal variability of ENSO teleconnections from changes related to increasing greenhouse concentrations. The current climate models also suffer from common biases, such that they are unable to properly reproduce both the tropical mean state and some features of ENSO. Nevertheless, observational records can be extended back in time via reconstruction methods. Efforts have also already been made to remove some main common biases of climate models and to improve the representation of ENSO characteristics. The reliable reconstructed data along with a large number of ensemble members of the improved climate model simulations can be applied to advance our understanding of ENSO global teleconnections and their responses to internal decadal variability and externally forced global warming. This article is categorized under: Paleoclimates and Current Trends > Modern Climate Change Climate Models and Modeling > Earth System Models Assessing Impacts of Climate Change > Evaluating Future Impacts of Climate Change
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