Responses of the East Asian Jet Stream to the North Pacific Subtropical Front in Spring

This study concerns atmospheric responses to the North Pacific subtropical front(NPSTF) in boreal spring over the period 1982–2014. Statistical results show that a strong NPSTF in spring can significantly enhance the East Asian jet stream(EAJS). Both transient eddy activity and the atmospheric heat source play important roles in this process. The enhanced atmospheric temperature gradient due to a strong NPSTF increases atmospheric baroclinicity, resulting in an intensification of transient eddy and convection activities. On the one hand, the enhanced transient eddy activities can excite an anomalous cyclonic circulation with a quasi-baraotropical structure in the troposphere to the north of the NPSTF. Accordingly, the related westerly wind anomalies around 30?N can intensify the component of the EAJS over the Northeast Pacific. On the other hand, an enhanced atmospheric heat source over the NPSTF, which is related to increased rainfall, acts to excite an anomalous cyclonic circulation system in the troposphere to the northwest of the NPSTF, which can explain the enhanced component of the EAJS over the Northwest Pacific. The two mechanisms may combine to enhance the EAJS.     

夏季逐月东亚高空西风急流经向偏移与热带中、东太平洋海温的关联

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.     

盛夏两类东亚高空西风急流北跳的动力过程

在气候态上,7月底东亚高空西风急流中心突然从40°N北跳到45°N以北.逐年统计分析显示此次急流北跳存在两类典型方式:急流北侧西风强度增强引起的北跳(第一类)和急流中心西风强度的减弱引起的北跳(第二类).本文基于1958年到2002年的NCEP/NCAR再分析资料,采用波活动通量诊断这两类典型北跳相应的动力过程,进一步...     

Connections between the Eurasian teleconnection and concurrent variation of upper-level jets over East Asia

The variation of the East Asian jet stream(EAJS) associated with the Eurasian(EU) teleconnection pattern is investigated using 60-yr NCEP–NCAR daily reanalysis data over the period 1951–2010. The EAJS consists of three components: the polar front jet(PFJ); the plateau subtropical jet(PSJ); and the ocean subtropical jet(OSJ). Of these three jets over East Asia,the EU pattern exhibits a significant influence on the PFJ and OSJ. There is a simultaneous negative correlation between the EU pattern and the PFJ. A significant positive correlation is found between the EU pattern and the OSJ when the EU pattern leads the OSJ by about 5 days. There is no obvious correlation between the EU pattern and the PSJ. The positive EU phase is accompanied by a weakened and poleward-shifted PFJ, which coincides with an intensified OSJ. A possible mechanism for the variation of the EAJS during different EU phases is explored via analyzing the effects of 10-day high-and low-frequency eddy forcing. The zonal wind tendency due to high-frequency eddy forcing contributes to the simultaneous negative correlation between the EU pattern and the PFJ, as well as the northward/southward shift of the PFJ. High- and low-frequency eddy forcing are both responsible for the positive correlation between the EU pattern and the OSJ, but only high-frequency eddy forcing contributes to the lagged variation of the OSJ relative to the EU pattern. The negative correlation between the EU pattern and winter temperature and precipitation anomalies in China is maintained only when the PFJ and OSJ are out of phase with each other. Thus, the EAJS plays an important role in transmitting the EU signal to winter temperature and precipitation anomalies in China.     

夏季北大西洋三极型海温异常与中国西南地区气温年际变化的联系

利用1951—2016年Hadley中心海温资料、NCEP/NCAR再分析资料和全国160站气温资料，研究了夏季北大西洋三极型海温异常与中国气温年际变化的联系及可能机制。结果表明，夏季北大西洋三极型海温异常与同期中国西南地区气温年际变化存在显著的负相关关系。夏季北大西洋“-+-”三极型海温异常激发的北半球中高纬欧亚遥相关波列，引起贝加尔湖地区位势高度升高，产生反气旋性环流异常，并引起东亚地区位势高度降低，产生气旋性环流异常。西南地区在对流层中下层位于贝加尔湖异常反气旋性环流的东部和东亚异常气旋性环流的西部，在两者的共同作用下，受异常偏北气流影响，有利于冷空气南下和堆积。与此同时，对流层高层的东亚副热带西风急流位置偏南，西南地区位于急流南侧的异常上升气流中。此种环流形势配置导致中国西南地区气温降低，反之亦然。     

夏季东亚高空西风急流气候特征分析

利用NCEP/NCAR全球再分析风场资料定义了西风急流强度指数和位置指数,然后利用EOF方法对西风急流进行了进一步的分析,分析了高空西风急流的空间分布特征,从强度和位置两方面分析了西风急流与东亚环流及其与海温的关系。分析表明： EOF第一模态反映了东亚高空急流的位置指数,第二模态反映了高空急流的强度指数。东亚高空急流与对流层大气环流包括南亚高压,西太平洋副热带高压,东亚夏季风存在着密切关系,其气候变化与热带副热带东太平洋、印度洋海温密切相关。     

中国北方季风区盛夏典型雨型的大气环流背景和海表温度演变特征

利用中国北方季风区46站盛夏降水观测资料,采用经验正交函数分解（EOF）、合成分析和相关分析等方法,将盛夏北方季风区划分为4类雨型:A型全区一致偏多、B型全区一致偏少、C型华北偏多东北偏少和D型华北偏少东北偏多,并对比分析了四类雨型同期大气环流和前期至同期海温演变特征的差异,以探讨其形成机制及前期预测信号。结果表明:四类雨型对应的东亚大气环流和海温演变具有明显的差异。A型年:东亚副热带西风急流（西风急流）和西太平洋副热带高压（西太副高）位置偏北,东亚夏季风偏强,欧亚中高纬以纬向环流为主,北方季风区低层辐合、高层辐散,冷暖空气在北方季风区辐合;从前冬至夏季,赤道中东太平洋类似于东部型La Ni?a发展年的海温异常分布,北大西洋海温三极子模态（NAT）负位相逐渐形成;B型年则基本相反。C（D）型年:西风急流异常偏北（略偏南）,西太副高偏西（东）偏北,华北盛行西南（西北）风,东北盛行东北（东南）风,华北地区对流层低层辐合（辐散）高层辐散（辐合）,东北地区对流层低层辐散（辐合）高层辐合（辐散）,东北冷涡较弱（活跃）;从前冬至夏季,赤道中东太平洋和印度洋逐渐由暖海温向冷海温转变（El Ni?o分布形态逐渐形成）。     

冬季东亚中纬度西风急流对我国气候的影响

利用1957—2001年欧洲中期数值天气预报中心再分析资料及地面台站观测资料，分析了冬季东亚西风急流与我国气候的关系。首先定义了冬季东亚西风急流强度指数(区域30°~35°N，127.5°~155°E冬季200 hPa纬向风u₂₀₀平均值的标准化值)和切变指数(区域15°~25°N，100°~115°E与区域30°~40°N，100°~115°E的平均u₂₀₀之差的标准化值)，这两个指数能较好地反映冬季东亚西风急流的强度变化和位置的南北移动，二者相关系数为-0.48，通过99%信度检验。西风急流强度与亚洲和西太平洋大范围的大气环流有密切关系，而西风急流位置移动则与印度洋、中东太平洋的大气环流有密切关系，并分析了冬季急流强度指数和切变指数与我国温度和降水的关系。结果表明:当西风急流强度偏强时，西风急流位置偏北，此时在急流入口区左侧由于气流辐合造成低层气压上升，在出口区左侧则由于气流发生强烈辐散，引起低层气压下降，所以西伯利亚地区上空从对流层低层到中层高度值升高，北太平洋高度值降低，东西向气压差加大的形势，同时东亚大槽偏强，海陆气压差加大和东亚大槽偏强，导致冬季风强度偏强，引起我国从北到南的陆面降温，同时30°~40°N低层有下沉气流，使得华北、华中和长江中下游地区降水偏少；当西风急流强度偏弱时，西风急流位置偏南，整个东亚地区存在南风异常，东亚冬季风较弱，在25°N附近有上升气流，此时华南和内蒙古、华北降水偏多，内蒙古地表温度偏高。     

西风角动量输送的气候特征及其与急流关系研究

利用1958～1997年NCEP/NCAR一日四次的风场再分析资料,系统地分析了季节平均西风角动量（即u角动量）经向、垂直输送通量及其三个分量（平均经圈环流、定常波、瞬变涡输送通量）的气候特征,特别是讨论了12～2月、6～8月它们与东、西风带、副热带西风急流、极夜急流之间的联系。结果表明:（1）包含纬度因子的角动量通量与动量通量在高纬地区存在显著差别,高纬对流层上部的强动量输送中心在角动量通量中不明显。而u角动量强经向输送主要在中低纬对流层顶附近和冬半球高纬平流层顶附近,副热带西风急流和极夜西风急流均位于u角动量强向极输送中心及其高纬一侧的辐合区中。（2）发现三个输送分量对急流维持的作用随纬度、季节不同。北半球冬季（夏季）的副热带西风急流主要由平均经圈环流（强度相当的定常波和瞬变涡）强经向输送及辐合维持;南半球西风急流全年均由平均经圈环流和瞬变涡旋输送及辐合维持;冬半球中平流层极夜急流主要由定常波、瞬变涡旋输送及其辐合共同维持。（3）热带东风区是牵连角动量（即Ω角动量）的高值区,它主要由平均经圈环流向对流层上部输送;冬半球副热带及中纬西风区存在u角动量垂直输送的切变区,它主要由平均经圈环流和瞬变涡旋完成;热带对流层顶附近有u角动量的定常波弱向下输送。     

青藏高原地表热通量变化及其对初夏东亚大气环流的影响

应用NCEP地面热通量资料, 研究了青藏高原地面感热、潜热的气候状况及其与初夏东亚大气环流之间的关系。发现高原地面热通量的异常将影响高原地区上空的垂直运动与辐散辐合运动, 从而引起东亚地区高度场及风场的异常。同时, 青藏高原地区地面热通量与后期东亚地区的环流变化也有密切关系, 这种关系可为预测东亚地区初夏环流异常提供有意义的指标。     

Observation of a summer tropopause fold by ozonesonde at Changchun,China: Comparison with reanalysis and model simulation

Tropopause folds are one of the key mechanisms of stratosphere-troposphere exchange (STE) in extratropical regions, transporting ozone-rich stratospheric air into the middle and lower troposphere. Although there have been many studies of tropopause folds that have occurred over Europe and North America, a very limited amount of work has been carried out over northeastern Asia. Ozonesondes produced by the Institute of Atmospheric Physics were launched in Changchun (43.9°N, 125.2°E), Northeast China, in June 2013, and observed an ozone-enriched layer with thickness of 3 km and an ozone peak of 180 ppbv at 6 km in the troposphere. The circulation field from the European Centre for Medium-Range Weather Forecasts Interim Reanalysis (ERA-Interim) dataset shows that this ozone peak was caused by a tropopause fold associated with a jet stream at the eastern flank of the East Asian trough. By analyzing the ozone data from the ozone monitoring instrument and Weather Research and Forecasting model with Chemistry (WRF-Chem) simulations, it was found that a high ozone concentration tongue originating from the lower stratosphere at high latitude (near central Siberia) intruded into the middle troposphere over Changchun between 5 and 8 km on 12 June 2013. The high-resolution WRF-Chem simulation was capable of describing events such as the tropopause fold that occurred on the cyclonic shear side of the jet stream. In addition, the TRAJ3D trajectory model was used to trace the origin of measured secondary ozone peaks in the middle troposphere back, for example, to stratospheric intrusion through the tropopause fold.     

Tropical cyclone potential hazard in Southeast China and its linkage with the East Asian westerly jet

A new synthesized index for estimating the hazard of both accumulated strong winds and heavy rainfall from a tropical cyclone (TC) is presented and applied to represent TC potential hazard over Southeast China. Its relationship with the East Asian westerly jet in the upper troposphere is also investigated. The results show that the new TC potential hazard index (PHI) is good at reflecting individual TC hazard and has significantly higher correlation with economic losses. Seasonal variation of TC-PHI shows that the largest TC-PHI on average occurs in July-August, the months when most TCs make landfall over mainland China. The spatial distribution of PHI at site shows that high PHI associated with major landfall TCs occurs along the southeast coast of China. An East Asian westerly jet index (EAWJI), which represents the meridional migration of the westerly jet, is defined based on two regions where significant correlations exist between TC landfall frequency and zonal wind at 200 hPa. Further analyses show that an anomalous easterly steering flow occurred above the tracks of TCs, and favored TCs making landfall along the southeast coast of China, leading to an increase in the landfall TC when the EAWJ was located north of its average latitude. Meanwhile, anomalous easterly wind shear and positive anomaly in low-level relative vorticity along TCs landfall-track favored TC development. In addition, anomalous water vapor transport from westerly wind in the South China Sea resulted in more condensational heating and an enhanced monsoon trough, leading to the maintenance of TC intensity for a longer time. All of these environmental factors increase the TC potential hazard in Southeast China. Furthermore, the EAWJ may affect tropical circulation by exciting meridional propagation of transient eddies. During a low EAWJI phase in July-August, anomalous transient eddy vorticity flux at 200 hPa propagates southward over the exit region of the EAWJ, resulting in eddy vorticity flux convergence and the weakening in the zonal westerly flow to the south of the EAWJ exit region, producing a favorable upper-level circulation for a TC making landfall.     

中东急流的季节变化特征及其与热力影响的关系

采用多年平均的NCEP/NCAR再分析资料,研究了中东急流强度和位置的季节变化特征及其与南北温差的关系。结果表明：1）中东地区上空西风带的强度和位置的垂直结构均具有明显的季节变化特征,冬、春季西风中心强度较大,夏、秋季西风中心强度较小;600hPa以上,冬、春季西风中心位置偏南,夏、秋季西风中心位置偏北。各季节的所有高度上,200hPa的西风中心风速最大。2）中东急流的强度和位置具有明显的季节变化特征。冬半年（11月—次年4月）中东急流较强,南北位置基本维持在27.5°N附近;夏半年（5—10月）中东急流较弱,5月后急流中心位置偏北,6—9月位于40°N附近,10月南撤至32.5°N。3）中东急流的强度和南北位置变化与500～200hPa整层平均的南北温差的对应关系很好,根据热成风原理,认为南北温差的季节性变化对中东急流的强度和南北位置变化具有重要影响。     

中国东部夏季降水与同期东亚副热带急流年代际异常的关系

利用中国738个台站的降水观测资料和NCEP/NCAR再分析资料, 分析了我国降水和200 hPa东亚副热带西风急流轴的年代际变化特征, 揭示了东亚副热带西风急流位置的南北移动与我国长江流域和华北降水异常之间的联系。结果表明, 我国东部地区夏季（7、 8月）降水异常主要表现为长江中下游地区多（少）雨, 华北及华南地区少（多）雨, 20世纪70年代末80年代初是这种异常分布型发生转折的时间。与此同时, 东亚高空副热带急流轴位置从70年代末开始逐渐偏南, 急流轴位置的变动将引起对流层低层水汽辐合区和高层散度分布以及垂直环流相应的变化, 进而引起降水区域的变化。相关分析发现, 当急流位置偏南时, 25°~35°N西风增强, 42°~50°N西风减弱, 华北夏季降水减少, 长江中下游地区夏季降水增多; 反之, 当急流位置偏北时, 华北夏季降水增多, 长江中下游地区夏季降水减少。与70年代末开始的我国东部地区急流轴位置逐渐南移相对应, 华北地区夏季降水呈现逐渐减少、 长江中下游地区夏季降水呈现逐渐增多的变化趋势。分析低层水汽通量和高层的散度分布以及垂直环流的差异发现, 1980年以来华北地区对流层中低层水汽通量辐合减弱, 水汽供应减少, 垂直上升运动减弱, 造成了华北夏季降水减少, 而长江中下游地区水汽通量辐合增加, 水汽供应增多, 垂直上升运动增强, 导致该地区降水增加。     

The coherent interdecadal changes of East Asia climate in mid-summer simulated by BCC_AGCM 2.0.1

This study proposes primary diagnostic metrics to evaluate the integrated structure of interdecadal changes of East Asian climate in mid-summer (July–August) over the recent half-century (1955–2000) in numerical models. The metrics are applied to comprehensively examine the performance of BCC_AGCM (Beijing Climate Center atmospheric general circulation model) version 2.0.1. When forced by historical sea surface temperatures (SST), the ensemble simulation with the BCC_AGCM reasonably reproduced the coherent interdecadal changes of rainfall, temperature and circulation. The main feature of the “southern-flooding-and-northern-drought” rainfall change is captured by the model. Correspondingly, the tropospheric cooling in the upper and middle troposphere, the southward shift of upper level westerly jet and weakening of the low-level southwesterly monsoon flow are also reproduced, as well as their relationships with rainfall changes. One of the main deficiencies of the simulation is that the amplitudes of the changes of tropospheric cooling and large-scale circulation are both much weaker than those in reanalysis, and they are consistent with the rainfall deficiency. Also, the upper and middle troposphere cooling center and decreasing of upper-level westerly jet axis shift westward in the model simulations compared with that in the observations. Overall, although BCC_AGCM shows problems in simulating the interdecadal changes of East Asia climate, especially the amplitude and locations of change centers, it reasonably represents the observed configuration of rainfall variation and the associated coherent temperature and circulation changes. Therefore, it could be further used to discuss the mechanisms of the interdecadal variation in East Asia. Meanwhile, the reasonably reproduced configuration of rainfall and its associated large-scale circulation by SST-forced runs indicate that the interdecadal variations in East Asia could mostly arise from the regional response to the global climate change.     

Interannual meridional displacement of the East Asian upper-tropospheric jet stream in summer

On the interannual timescale, the meridional displacement of the East Asian upper-tropospheric jet stream (EAJS) is significantly associated with the rainfall anomalies in East Asia in summer. In this study, using the data from the National Centers for Environmental Prediction-Department of Energy (NCEP/DOE) reanalysis-2 from 1979 to 2002, the authors investigate the interannual variations of the EAJS‘s meridional displacement in summer and their associations with the variations of the South Asian high (SAH) and the western North Pacific subtropical high (WNPSH), which are dominant circulation features in the upper and lower troposhere, respectively. The result from an EOF analysis shows that the meridional displacement is the most remarkable feature of the interannual variations of the EAJS in each month of summer and in summer as a whole. A composite analysis indicates that the summer (June-July-August, JJA) EAJS index, which is intended to depict the interannual meridional displacement of the EAJS, is not appropriate because the anomalies of the zonal wind at 200 hPa (U200) in July and August only, rather than in June, significantly contribute to the summer EAJS index. Thus, the index for each month in summer is defined according to the location of the EAJS core in each month. Composite analyses based on the monthly indexes show that corresponding to the monthly equatorward displacement of the EAJS, the South Asian high (SAH) extends southeastward clearly in July and August, and the western North Pacific subtropical high (WNPSH) withdraws southward in June and August.     

CHARACTERISTICS OF MIDDLE EAST JET STREAM DURING SEASONAL TRANSITION AND ITS RELATION WITH INDIAN SUMMER MONSOON ONSET?

By using the NCEP/NCAR pentad reanalysis data from 1968 to 2009, the variation characteristics of Middle East jet stream(MEJS) and its thermal mechanism during seasonal transition are studied. Results show that the intensity and south-north location of MEJS center exhibit obvious seasonal variation characteristics. When MEJS is strong, it is at 27.5°N from the 67 th pentad to the 24 th pentad the following year; when MEJS is weak, it is at 45°N from the 38 th pentad to the 44 th pentad. The first Empirical Orthogonal Function(EOF) mode of 200-hPa zonal wind field shows that MEJS is mainly over Egypt and Saudi Arabia in winter and over the eastern Black Sea and the eastern Aral Sea in summer. MEJS intensity markedly weakens in summer in comparison with that in winter. The 26th-31 st pentad is the spring-summer transition of MEJS, and the 54th-61 st pentad the autumn-winter transition. During the two seasonal transitions, the temporal variations of the 500-200 hPa south-north temperature difference(SNTD) well match with 200-hPa zonal wind velocity, indicating that the former leads to the latter following the principle of thermal wind. A case analysis shows that there is a close relation between the onset date of Indian summer monsoon and the transition date of MEJS seasonal transition. When the outbreak date of Indian summer monsoon is earlier than normal, MEJS moves northward earlier because the larger SNTD between 500-200 hPa moves northward earlier, with the westerly jet in the lower troposphere over 40°-90°E appearing earlier than normal, and vice versa.     

Satellite Measurements of the Madden–Julian Oscillation in Wintertime Stratospheric Ozone over the Tibetan Plateau and East Asia

We investigate the Madden–Julian Oscillation(MJO) signal in wintertime stratospheric ozone over the Tibetan Plateau and East Asia using the harmonized dataset of satellite ozone profiles. Two different MJO indices — the all-season Real-Time multivariate MJO index(RMM) and outgoing longwave radiation-based MJO index(OMI) — are used to compare the MJOrelated ozone anomalies. The results show that there are pronounced eastward-propagating MJO-related stratospheric ozone anomalies(mainly within 20–200 h Pa) over the subtropics. The negative stratospheric ozone anomalies are over the Tibetan Plateau and East Asia in MJO phases 4–7, when MJO-related tropical deep convective anomalies move from the equatorial Indian Ocean towards the western Pacific Ocean. Compared with the results based on RMM, the MJO-related stratospheric column ozone anomalies based on OMI are stronger and one phase ahead. Further analysis suggests that different sampling errors, observation principles and retrieval algorithms may be responsible for the discrepancies among different satellite measurements. The MJO-related stratospheric ozone anomalies can be attributed to the MJO-related circulation anomalies,i.e., the uplifted tropopause and the northward shifted westerly jet in the upper troposphere. Compared to the result based on RMM, the upper tropospheric westerly jet may play a less important role in generating the stratospheric column ozone anomalies based on OMI. Our study indicates that the circulation-based MJO index(RMM) can better characterize the MJOrelated anomalies in tropopause pressure and thus the MJO influence on atmospheric trace gases in the upper troposphere and lower stratosphere, especially over subtropical East Asia.     

夏季东亚高空急流与天气尺度波动的气候特征之间的联系

利用NCEP/NCAR逐日资料(1979~2003年),分析了东亚夏季高空急流和天气尺度波动气候特征之间的联系。通过分析急流与天气尺度波动活动量Q(用于描述某一时间段内天气尺度波动活动强弱程度)、热量涡动输送(V′T′)的关系,发现:在气候平均意义下,天气尺度波动活动量在6、8月较大,这意味着在这两个月中,天气尺度波动较为剧烈。这和急流的强度变化是相对应的,即强的天气尺度波动活动量对应着强的急流,弱的天气尺度波动活动量对应着弱的急流。热量涡动输送也表现出与天气尺度波动活动量类似的特征。年际变化上,夏季平均和6、7、8各月平均的热量涡动输送和急流强度都存在显著的正相关。对强、弱急流年份条件下热量涡动输送合成分析的结果表明:热量涡动输送偏南时,对应着强的急流;热量涡动输送偏北时,对应着弱的急流。以上的研究结果说明,在气候平均意义和年际变化上夏季东亚高空急流和天气尺度波动之间有着密切的联系。     

The East Asian Upper-Tropospheric Jet Streams and Associated Transient Eddy Activities Simulated by a Climate System Model BCC_CSM1.1

In this paper, major features of the upper-tropospheric jet streams simulated by a coupled Climate System Model BCC_CSM1.1 are evaluated through comparison with the NCEP/NCAR reanalysis. The jet streams consist of the East Asian subtropical jet (EASJ) and the East Asian polar-front jet (EAPJ). Associated stationary wave and synoptic-scale transient eddy activities (STEA) are also examined. The results show that the climatological positions of the westerly jet streams are well captured by BCC_CSM1.1, but with slight intensity biases. Statistics from the 6-h model outputs reveal that the jet core number (JCN) of ESPJ is significantly underestimated. Examination of the simulated seasonal evolution of the westerly jet stream indicates that the model has produced a westward movement of the EASJ core in May, one month earlier than that in the reanalysis. Analysis of stationary wave activities shows that the overestimated meridional wind component may have caused considerable enhancement of meridional momentum and heat transport. The stationary Rossby wave represented by the wave activity flux at the southern flank of the Tibetan Plateau is favorable to the growth of asymmetric zonal wind and the multiple-center pattern of JCN. Unlike the stationary wave heat flux transport, the model tends to systematically generate weaker transient heat flux over East Asia. Further analysis of STEA exhibits a general consistent pattern between the simulation and the reanalysis, while the intensity of the northern STEA branch associated with the EAPJ is greatly reduced. The deficiencies of eddy momentum and heat flux transport and accompanied eddy forcing may contribute to the biases of the simulated upper-tropospheric jet streams, suggesting the potential importance of midlatitude internal atmospheric dynamics in shaping the tropospheric general circulation, which is not yet fully and accurately resolved in the current BCC_CSM1.1.