CMIP5多模式模拟两类El Ni(n)o海表盐度分布及与降水的关系

利用CMIP5提供的25个工业革命前控制试验(piControl)模拟数据评估了热带太平洋两类El Ni(n)o(即东部EP和中部CP型El Ni(n)o)的海表盐度(SSS)空间结构差异及其与海表温度(SST)和降水的关系.结果表明:(1)大部分模式能够模拟出EP和CP型空间结构,两类El Ni(n)o中的SST、降水和SSS的空间技巧评分依次减小,其中,EP型SST和降水水平分布的模拟能力强于CP型,SSS则为CP型强于EP型,CP型模拟的SST、SSS和降水异常中心位置较EP型偏西且强度偏弱;(2) CP型SST、降水和SSS三者空间分布的线性一致性比EP型好,即在CP型中,SST影响降水,进而影响SSS,同时SSS对SST调制的反馈机制较显著,而对于EP型,由于海洋水平平流和非局地效应等因素,使得SST与SSS空间对应较差;(3)依据多模式模拟的SSS空间技巧评分高低将CMIP5模式分为两类,技巧评分低(高)的模式模拟的SST、SSS和降水异常值的中心位置偏西(偏东),引起中心位置偏移的原因与模式模拟赤道太平洋冷舌的位置有关,即赤道太平洋冷舌西伸显著,导致发生El Ni(n)o时SST异常变暖西伸显著,进而使得降水异常和SSS异常位置偏西.同时,技巧评分低的模式还易出现向东南延伸的负SSS异常,原因是双赤道辐合带的东南分支过于明显,即降水偏多,导致SSS偏淡.SSS变化会影响ENSO的发生发展.因此,探讨两类El Ni(n)o盐度分布的差异及相关物理场的关系,为提高模式的气候模拟和预测提供有益的借鉴.     

不同类型和强度的厄尔尼诺事件对次年华南前汛期降水的可能影响

根据气象行业标准（QT/T370-2017）对厄尔尼诺事件不同类型的划分结果以及国家气候中心最新颁布的华南前汛期业务监测标准,利用1961~2016年NCEP/NCAR日、月尺度再分析大气环流资料、海表温度资料（ERSST V4）以及华南261个国家气象观测站逐日降水资料,采用相关、合成等方法分析了不同类型、强度的厄尔尼诺事件特征以及与次年华南前汛期的关系,并探讨其海温和大气环流异常特征。结果表明,厄尔尼诺事件的类型、强度对次年华南前汛期降水的影响存在明显差异。中等及以上强度东部型厄尔尼诺事件次年,华南前汛期开汛早、结束晚,前汛期持续时间长、降水多;弱等级的东部型以及中部型厄尔尼诺事件次年则相反。在厄尔尼诺事件次年华南前汛期,中等及以上强度东部型厄尔尼诺相对弱东部型或中部型厄尔尼诺的大气环流存在明显差异。高层西风急流明显加强,中层北半球极涡加强,东亚大槽强,低层菲律宾以东存在反气旋异常环流,华南存在南北风的交汇和水汽辐合加强,有利于华南前汛期降水偏多。     

下边界条件对北极涛动影响的数值模拟研究

利用NCAR大气模式CAM3.0探讨了包括山脉和海陆分布等下边界条件对北极涛动(AO)或北半球环状模(NAM)形成的影响.主要进行了控制试验和两个地形敏感性数值试验,对比了控制试验结果与资料分析结果.控制试验和NCEP/NCAR资料分析结果对比指出,CAM3.0模式能够较好地模拟出AO的水平环状结构和垂直相当正压结构.在去除山脉的敏感性试验中发现,AO中纬度北太平洋和北大西洋两个活动中心的强度、范围和位置发生变化.在水球敏感性试验中发现,AO两个大洋上的活动中心被环绕极地主活动中心的环状结构代替.两个敏感性试验共同表明,AO是大气内部某种过程作用的结果,它的存在本身不取决于下边界条件的改变.山脉和海陆分布主要影响的是AO的具体形态.通过控制试验和两个敏感性试验对比,又分析了准定常波和瞬变波对AO的影响.去除山脉和海陆分布热力差异共同强迫的准定常波,AO纬向平均纬向风高纬地区平流层异常最大值活动中心消失,这表明在平流层准定常波和纬向平均流的相互作用与AO活动关系密切.在只有对流层瞬变波作用时,AO仍然存在,表明准定常波不是AO存在的必要条件.平流层准定常波与平均流的相互作用和对流层瞬变波与平均流的相互作用与AO形成之间的具体关系有待通过E-P通量诊断进一步确定.     

Relationship between the Late Spring NAO and Summer Extreme Precipitation Frequency in the Middle and Lower Reaches of the Yangtze River

The relationship between the late spring North Atlantic Oscillation (NAO) and the summer extreme precipitation frequency (EPF) in the middle and lower reaches of the Yangtze River Valley (MLYRV) is examined using an NECP/NCAR reanalysis dataset and daily precipitation data from 74 stations in the MLYRV. The results show a significant negative correlation between the May NAO index and the EPF over the MLYRV in the subsequent summer. In positive EPF index years, the East Asian westerly jet shifts farther southward, and two blocking high positive anomalies appear over the Sea of Okhotsk and the Ural Mountains. These anomalies are favorable to the cold air from the mid-high latitudes invading the Yangtze River Valley (YRV). The moisture convergence and the ascending motion dominate the MLYRV. The above patterns are reversed in negative EPF index years. A wave train pattern that originates from the North Atlantic extends eastward to the Mediterranean and then moves to the Tibetan Plateau and from there to the YRV, which is an important link in the May NAO and the summer extreme precipitation in the MLYRV. The wave train may be aroused by the tripole pattern of the SST, which can explain why the May NAO affects the summer EPF in the MLYRV.     

滤除ENSO信号前后夏季热带印度洋海盆尺度海温距平对西太平洋副热带高压的不同影响

使用NCEP/NCAR再分析资料、哈得来海表温度和中国国家气候中心的西太平洋副热带高压（西太副高）特征指数,对比分析了ENSO背景下的夏季印度洋海盆尺度模（Indian Ocean basin mode,IOBM）与独立于ENSO的纯IOBM（pure Indian Ocean basin mode,IOBM_P）对西太副高的影响机理。结果表明,滤除前期ENSO信号后,西北太平洋上为海温负距平,并在其西北侧强迫出Gill型反气旋。另外,印度洋与海洋性大陆间存在西高东低的海温距平梯度,印度洋正、负海温距平激发出的赤道开尔文波影响至海洋性大陆西部地区,强迫出的异常大气环流关于赤道基本对称。加之此时中国南海至西北太平洋地区降水偏弱,潜热释放偏少,从而非绝热冷却,导致西太副高异常偏强、偏南。而在前期厄尔尼诺的影响下,次年夏季印度洋与海洋性大陆地区均有利于出现海温正距平,开尔文波的影响偏强、偏东,强迫出的异常环流偏向北半球,通过“埃克曼抽吸”和非绝热冷却在对流层低层制造出异常负涡度进而影响西太副高,使其明显偏强、偏西、偏南。由于IOBM_P在2和8年周期上对西太副高的影响最明显,而ENSO信号中主要是3—7 a的短周期振荡,因此,ENSO背景下的印度洋变暖对西太副高的遥强迫实际包含了来自热带中太平洋的3—7 a周期信号的滞后影响和印度洋地区局地变化特别是2和8年周期变化的作用。这些结果为人们深入理解西太副高变化规律和做出有效预报提供了线索。      

Toward Understanding the Extreme Floods over Yangtze River Valley in June?July 2020: Role of Tropical Oceans※

The extreme floods in the Middle/Lower Yangtze River Valley (MLYRV) during June?July 2020 caused more than 170 billion Chinese Yuan direct economic losses. Here, we examine the key features related to this extreme event and explore relative contributions of SST anomalies in different tropical oceans. Our results reveal that the extreme floods over the MLYRV were tightly related to a strong anomalous anticyclone persisting over the western North Pacific, which brought tropical warm moisture northward that converged over the MLYRV. In addition, despite the absence of a strong El Ni?o in 2019/2020 winter, the mean SST anomaly in the tropical Indian Ocean during June?July 2020 reached its highest value over the last 40 years, and 43％ (57％) of it is attributed to the multi-decadal warming trend (interannual variability). Based on the NUIST CFS1.0 model that successfully predicted the wet conditions over the MLYRV in summer 2020 initiated from 1 March 2020 (albeit the magnitude of the predicted precipitation was only about one-seventh of the observed), sensitivity experiment results suggest that the warm SST condition in the Indian Ocean played a dominant role in generating the extreme floods, compared to the contributions of SST anomalies in the Maritime Continent, central and eastern equatorial Pacific, and North Atlantic. Furthermore, both the multi-decadal warming trend and the interannual variability of the Indian Ocean SSTs had positive impacts on the extreme floods. Our results imply that the strong multi-decadal warming trend in the Indian Ocean needs to be taken into consideration for the prediction/projection of summer extreme floods over the MLYRV in the future.     

MJO对我国降水影响的季节调制和动力-统计降尺度预测

利用1981—2016年中国区域CN05.1格点降水资料和EAR-Interim再分析资料,研究了季节循环对于热带大气季节内振荡(MJO)对我国降水影响的调制作用,并基于模式对MJO的预报建立了针对延伸期降水的动力-统计降尺度模型。结果表明,MJO对我国季节内降水异常的影响明显受到季节循环的调制。当MJO对流在热带印度洋活跃时,我国降水偏多的区域随季节由南向北推进;当MJO对流位于海洋性大陆地区时,在秋、冬季我国东部和高原大部分地区降水异常偏少,而到了春、夏季该关系反转。MJO对流和基本气流(特别是副热带西风急流)的位置和强度的变化所引起热带外环流响应的不同是造成这种季节性差异的重要原因。模式检验表明,BCC_AGCM2.2对目标候MJO的预报技巧可达18d以上,在此基础上利用模式预报MJO信息构建了随季节演变滚动的MJO动力-统计降尺度预测模型。独立样本检验表明,该模型在较长时效(10~20d)下对MJO高影响区低频降水异常的预报技巧高于模式的直接预报,特别是在MJO活跃时期对降水预报技巧的提升更加明显,这为MJO信号释用提供了新的思路。     

Interdecadal Variability of the Afro-Asian Summer Monsoon System

The Afro-Asian summer monsoon is a zonally planetary-scale system, with a large-scale rainbelt covering Africa, South Asia and East Asia on interdecadal timescales both in the past century(1901–2014) and during the last three decades(1979–2014). A recent abrupt change of precipitation occurred in the late 1990 s. Since then, the entire rainbelt of the Afro-Asia monsoon system has advanced northwards in a coordinated way. Consistent increases in precipitation over the Huanghe–Huaihe River valley and the Sahel are associated with the teleconnection pattern excited by the warm phase of the Atlantic Multidecadal Oscillation(AMO). A teleconnection wave train, with alternating cyclones/anticyclones, is detected in the upper troposphere. Along the teleconnection path, the configuration of circulation anomalies in North Africa is characterized by coupling of the upper-level anticyclone(divergence) with low-level thermal low pressure(convergence), facilitating the initiation and development of ascending motions in the Sahel. Similarly, in East Asia, a coupled circulation pattern also excites ascending motion in the Huanghe–Huaihe River valley. The synchronous increase in precipitation over the Sahel and Huanghe–Huaihe River valley can be attributed to the co-occurrences and in-phase changes of ascending motion. On the other hand, the warm phase of the AMO results in significant warming in the upper troposphere in North Africa and the northern part of East Asia. Such warming contributes to intensification of the tropical easterly jet through increasing the meridional pressure gradient both at the entrance region(East Asia) and the exit region(Africa). Accordingly, precipitation over the Sahel and Huanghe–Huaihe River valley intensifies, owing to ageostrophic secondary cells. The results of this study provide evidence for a consistent and holistic interdecadal change in the Afro-Asian summer monsoon.     

Dynamic Mechanism of Interannual Sea Surface Height Variability in the North Pacific Subtropical Gyre

In this study, the dynamic mechanisms of interannual sea surface height (SSH) variability are investigated based on the first-mode baroclinic Rossby wave model, with a focus on the effects of different levels of wind stress curl (WSC). Maximum covariance analysis (MCA) of WSC and SSH anomalies displays a mode with significant WSC anomalies located primarily in the mid-latitude eastern North Pacific and central tropical Pacific with corresponding SSH anomalies located to the west. This leading mode can be attributed to Ekman pumping induced by local wind stress and the westward-propagating Rossby wave driven by large- scale wind stress. It is further found that in the middle latitudes, the SSH anomalies are largely determined by WSC variations associated with the North Pacific Gyre Oscillation (NPGO), rather than the Pacific Decadal Oscillation (PDO). The sensitivity of the predictive skill of the linear first-mode baroclinic model to different wind products is also examined.     

The Role of the Solar Cycle in the Relationship Between the North Atlantic Oscillation and Northern Hemisphere Surface Temperatures

The North Atlantic Oscillation （NAO） is one of the leading modes of climate variability in the Northern Hemisphere. It has been shown that it clearly relates to changes in meteorological variables, such as surface temperature, at hemispherical scales. However, recent studies have revealed that the NAO spatial pattern also depends upon solar forcing. Therefore, its effects on meteorological variables must vary depending upon this factor. Moreover, it could be that the Sun affects climate through variability patterns, a hypothesis that is the focus of this study. We find that the relationship between the NAO/AO and hemispheric temperature varies depending upon solar activity. The results show a positive significant correlation only when solar activity is high. Also, the results support the idea that solar activity influences tropospheric climate fluctuations in the Northern Hemisphere via the fluctuations of the stratospheric polar vortex .