Simple Metrics for Representing East Asian Winter Monsoon Variability:Urals Blocking and Western Pacific Teleconnection Patterns

Instead of conventional East Asian winter monsoon indices （EAWMIs）, we simply use two large-scale teleconnection patterns to represent long-term variations in the EAWM. First, the Urals blocking pattern index （UBI） is closely related to cold air advection from the high latitudes towards western Siberia, such that it shows an implicit linkage with the Siberian high intensity and the surface air temperature （SAT） variations north of 40°N in the EAWM region. Second, the well-known western Pacific teleconnection index （WPI） is connected with the meridional displacement of the East Asian jet stream and the East Asian trough. This is strongly related to the SAT variations in the coastal area south of 40°N in the EAWM region. The temperature variation in the EAWM region is also represented by the two dominant temperature modes, which are called the northern temperature mode （NTM） and the southern temperature mode （STM）. Compared to 19 existing EAWMIs and other well-known teleconnection patterns, the UBI shows the strongest correlation with the NTM, while the WPI shows an equally strong correlation with the STM as four EAWMIs. The UBI-NTM and WPI-STM relationships are robust when the correlation analysis is repeated by （1） the 31-year running correlation and （2） the 8-year high-pass and low-pass filter. Hence, these results are useful for analyzing the large-scale teleconnections of the EAWM and for evaluating this issue in climate models. Int particular, more studies should focus on the teleconnection patterns over extratropical Eurasia.

Intercomparison of the Impacts of Four Summer Teleconnections over Eurasia on East Asian Rainfall

East Asian summer climate is strongly affected by extratropical circulation disturbances.In this study,impacts of four atmospheric teleconnections over Eurasia on East Asian summer rainfall are investigated using National Centers for Environmental Prediction/National Center for Atmospheric Research （NCEP/NCAR） reanalysis data and Climatic Research Unit （CRU） land precipitation data during 1979-2009.The four teleconnections include the Scandinavian （SCA）,the Polar/Eurasian （PEU）,the East Atlantic/Western Russian （EAWR）,and the circumglobal teleconnection （CGT）.Moreover,the related changes of lower-tropospheric circulation are explored,specifically,the low pressure over northern East Asia （NEAL） and the subtropical high over the western North Pacific （WNPSH）.The results presented are in the positive phase.The PEU and SCA induce significant negative anomalies in North China rainfall （NCR）,while the CGT induces significant positive anomalies.In the past three decades,the PEU and SCA explain more than 20％ of the variance in NCR,twice that explained by the CGT,suggesting a more important role of the former two teleconnections in NCR variation than the latter one.Meanwhile,the PEU and SCA reduce rainfall in Northeast China and South Korea,respectively,and the CGT enhances rainfall in Japan.The rainfall responses are attributed to the SCA-induced northward shift of the NEAL,and PEU-induced northward shift and weakening of the NEAL,respectively.For the CGT,the dipole pattern of rainfall anomalies between North China and Japan is affected by both westward extension of the NEAL and northwestward expansion of the WNPSH.In addition,the EAWR leads to an increase of sporadic rainfall in South China as a result of the eastward retreat of the WNPSH.

Relationship between Meridional Displacement of the Monthly East Asian Jet Stream in the Summer and Sea Surface Temperature in the Tropical Central and Eastern Pacific

Previous studies have shown that meridional displacement of the East Asian upper-tropospheric jet stream (EAJS) dominates interannual variability of the EAJS in the summer months.This study investigates the tropical Pacific sea surface temperature (SST) anomalies associated with meridional displacement of the monthly EAJS during the summer.The meridional displacement of the EAJS in June is significantly associated with the tropical central Pacific SST anomaly in the winter of previous years,while displacements in July and August are related to tropical eastern Pacific SST anomalies in the late spring and concurrent summer.The EAJS tends to shift southward in the following June (July and August) corresponding to a warm SST anomaly in the central (eastern) Pacific in the winter (late spring-summer).The westerly anomaly south of the Asian jet stream is a result of tropical central Pacific warm SST anomaly-related warming in the tropical troposphere,which is proposed as a possible reason for southward displacement of the EAJS in June.The late spring-summer warm SST anomaly in the tropical eastern Pacific,however,may be linked to southward displacement of the EAJS in July and August through a meridional teleconnection over the western North Pacific (WNP) and East Asia.

Unprecedented East Asian warming in spring 2018 linked to the North Atlantic tripole SST mode

An unusually warm East Asia in spring 2018,when exceptionally high surface air temperatures were recorded in large areas of Asia,such as northern China,southern China,and Japan,was investigated based on the ERA-Interim reanalysis.The East Asian warming anomalies were primarily attributed to a tripole mode of North Atlantic SST anomalies,which could have triggered anomalous Rossby wave trains over the North Atlantic and Eurasia through modulating the North Atlantic baroclinic instability.Atlantic-forced Rossby waves tend to propagate eastward and induce anomalously high pressure and anticyclonic activity over East Asia,leading to a northward displacement of the Pacific subtropical high.As a result,descending motion,reduced precipitation,and increased surface solar radiation due to less cloud cover appear over East Asia,accompanied by remarkably warm advection from the ocean to southern China,northern China,and Japan.The transportation of anomalously warm advection and the feedbacks between soil moisture and surface temperature were both favorable for the recordbreaking warmth in East Asia during spring 2018.The seasonal‘memory’of the North Atlantic tripole SST mode from the previous winter to the following spring may provide useful implications for the seasonal prediction of East Asian weather and climate.

12月和2月热带太平洋海温与东亚水汽输送关系的年代际变化机制

利用1950~2019年NCEP/NCAR大气再分析资料、NOAA海表面温度资料以及ERA5垂直积分水汽通量资料,分析了12月和2月热带中东太平洋海温与东亚水汽输送关系的年代际变化。结果表明,12月东亚上空经向水汽输送与热带中东太平洋海温的相关性在1980年代中期之前较弱,1980年代中期之后二者呈显著正相关;2月二者关系在1950~1970年和1990~2010年呈显著正相关。12月二者关系年代际变化的主要原因是热带太平洋海温通过太平洋—东亚(PEA)遥相关型和环北半球遥相关型对东亚水汽输送的影响在1980年代中期之后增强;当热带中东太平洋海温偏暖(冷)时,影响PEA遥相关型和环北半球遥相关型,导致东亚自南向北的水汽输送异常增强(减弱)。与12月不同的是,2月二者关系在1950~1970和1990~2010年主要受PEA遥相关型影响。而在1971~1989期间,2月二者关系受环北半球遥相关型影响;当热带太平洋海温偏冷(暖)时,影响环北半球遥相关型,导致东亚经向水汽输送异常增强(减弱),该机制可以部分抵消PEA机制对东亚水汽输送的影响,导致二者关系在此期间不显著。此外1990年之后,热带印度洋海温对12月和2月东亚经向水汽输送的影响增强,在12月热带印度洋海温主要通过“开尔文波—埃克曼辐散”效应影响东亚经向水汽输送,而在2月主要通过印度洋上的沃克环流影响东亚经向水汽输送。

东亚季风系统的动力过程和准定常行星波活动的研究进展

本文系统地回顾了近几年来关于东亚季风系统的动力过程与机理方面的研究,特别是关于东亚季风系统年际和年代际变异与准定常行星波活动关系的研究。最近的许多研究表明东亚夏季风系统变异的动力过程主要与东亚/太平洋型(即EAP型)遥相关有关,利用EAP型遥相关理论不仅可以说明东亚夏季风系统各成员之间内在联系的机理,而且可以揭示热带西太平洋热力和菲律宾周围对流活动影响东亚夏季风系统季节内、年际变化及其异常的经向三极子结构的动力过程;除了EAP型遥相关外,研究还表明北半球夏季从北非到东亚的对流层上层经向风异常存在一个沿急流传播的遥相关型,它对东亚夏季风系统异常的经向三极子型分布也有重要影响。并且,最近关于东亚冬季风变异与行星波活动的关系已做出许多研究,并获得很大进展。这些研究表明:北半球冬季准定常行星波传播波导在年际和年代际变化上存在着反相振荡特征,即若"极地波导"加强,则"低纬波导"将减弱,反之亦然;准定常行星波两支波导的反相振荡与北半球环状模(NAM)的年际和年代际振荡有紧密联系,而NAM的变化通过行星波活动的异常可以导致东亚冬季风的年际和年代际变化;此外,准定常行星波活动的年际变化与东亚冬季风异常之间的关系明显地受热带平流层纬向风准两年周期振荡(QBO)的调制,进一步的研究还提出了可能的机理。最后本文还指出:2005～2007年冬季东亚冬季风的异常不仅与西伯利亚高压和阿留申低压的变异有关,而且与极涡的演变和准定常行星波活动密切相关。

欧亚积雪异常分布对冬季大气环流的影响I.观测研究

利用ECMWF 1 979～ 1 993年 2 5°× 2 5°的网格点积雪深度资料、中国气象局整编的海平面气压、 5 0 0hPa高度场和NCEP再分析资料 ,探讨了欧亚冬季积雪异常对同期大气环流的影响。结果表明 :( 1 )欧亚中高纬冬季积雪面积与同期大气环流具有密切的联系 :积雪面积为正 (负 )异常时 ,冬季 5 0 0hPa高度场对应正 (负 )欧亚—太平洋 (简称EUP)遥相关型 ,东亚冬季风活动偏强 (弱 )。 ( 2 )诊断结果表明 ,积雪异常与大气环流之间的密切联系在一定程度上反映了冬季积雪的异常分布可能对大气EUP遥相关型和东亚冬季风活动产生影响。 ( 3)SVD分析得到的冬季积雪的异常分布与同期大气环流的耦合模态 ,证实了前面所得结果。

东亚-太平洋型季节内演变和维持机理研究

利用850 hPa的纬向风异常建立一个逐候东亚-太平洋(East Asian Pacific,EAP)型指数,研究其季节内演变特征,发现东亚-太平洋型经向波列是东亚夏季风季节内变化的主要模态。其演变过程为:扰动首先出现在北太平洋中部,并通过正压不稳定过程从基本气流中获得能量而发展,在高层罗斯贝波能量向南频散,激发热带对流异常和赤道罗斯贝波,并相互锁相,因赤道罗斯贝波受β效应影响而共同向西移动。热带对流和环流异常在菲律宾附近达到最强,此时在东亚沿岸出现经向三极型波列,此后中低纬度异常继续向西北方向移动,使降水异常在长江流域能维持较长时间。东亚-太平洋型在东亚发展和维持有以下原因:首先,菲律宾暖水上空的对流和低层环流之间存在正反馈;其次,由于海陆热力差异导致暖大陆和冷海洋之间存在特殊的纬向温度梯度和北风垂直切变,东亚-太平洋型在经向上有向北倾斜的斜压结构,能通过斜压能量转换从平均有效位能中获得能量,同时,也能从经向温度梯度的平均有效位能中获得能量。

冬季北太平洋涛动异常与东亚冬季风和我国天气气候的关系

用1948—2000年的北半球海平面气压场月平均资料,计算了北太平洋涛动指数和东亚冬季风指数,并研究了北太平洋涛动与东亚冬季风及我国冬季天气气候的关系。研究表明,北太平洋涛动异常变化与我国冬季天气、气候关系密切。强涛动年,东亚冬季风偏弱,我国气温普遍偏高,长江中下游地区降水偏少,而华南降水偏多;而弱涛动指数年,东亚冬季风偏强,我国气温普遍偏低,降水偏少。此外,还指出,强(弱)INPO年大气环流具有弱(强)WP型和强(弱)EU遥相关型。

夏季东亚高空急流与太平洋-日本遥相关型的关系（英文）

利用NCEP/NCAR和NOAA月平均资料,采用奇异值分解方法分析了夏季东亚高空纬向风场和西北太平洋海表温度(SST)的耦合关系,并据此研究了东亚副热带高空急流和太平洋-日本(Pacific-Japan,PJ)遥相关型的可能联系。合成分析结果表明,东亚副热带高空急流正模态年,急流偏南偏强,对流层上层南亚高压增强东进,中层西太平洋副热带高压加强西伸,菲律宾周边海域SST升高,中纬度黑潮延伸体区SST降低,菲律宾海和热带西太平洋地区对流活动偏弱,日本海和黑潮延伸体海区对流活动增强,对应PJ遥相关型的负位相;而东亚副热带高空急流负模态年,急流偏北偏弱,对流层上层南亚高压减弱西退,中层西太平洋副热带高压减弱东撤,菲律宾周边SST降低,中纬度黑潮延伸体区SST升高,菲律宾海和热带西太平洋地区对流活动强盛,日本海和黑潮延伸体海区对流活动减弱,对应PJ遥相关型的正位相。由于夏季东亚副热带高空急流活动与PJ遥相关型存在关联,PJ遥相关型可能是东亚副热带高空急流响应太平洋海温异常的纽带。

南半球环状模对中国气候的影响研究进展

南半球环状模是南半球大气环流年际变异的主导模态。按照逻辑脉络梳理了半个多世纪以来南半球环状模对中国气候影响的研究进展。中国科学家很早就注意到南北半球之间存在相互作用,南半球环流能够通过越赤道气流调控东亚夏季风、进一步影响到中国气候。近年来,对南半球环状模遥相关效应的研究愈加深入,已有工作侧重于从太平洋通道和印度洋通道两个角度剖析环状模对中国气候的影响。环状模变异能够引发太平洋大气经圈环流调整、激发经向遥相关波列,从而引起西太平洋暖池和西太平洋副热带高压异常,最终导致中国气候变异,从而构建了太平洋路径;另一方面,环状模异常也能够借助"海洋桥"传播到热带印度洋和南海地区、再通过局地海洋-大气相互作用调控中国气候,从而构建了印度洋路径。两大路径之间存在相互调制。除此之外,南半球环状模对中国区域气候也有显著的影响。在总结前人研究的基础上,提出了今后值得深入探讨的几个问题,以期推动南半球环状模遥相关效应研究不断走向深入。

The East Asian summer monsoon circulation anomaly index and its interannual variations

Based on the concept of East Asia-Pacific (EAP) teleconnection which influences East Asian summer monsoon, an index for East Asian summer monsoon circulation anomaly was defined and it was pointed out that this index can describle the interannual variation character of summer climate in East Asia, especially in the Yangtze River and Huaihe River Valley.