北太平洋冬季次表层热状况及其与中国东部夏季气候的关系

利用北太平洋次表层海温及热容量资料和我国160个台站1951-2002年夏季(6-8月)降水、气温资料,分析了北太平洋冬季次表层热状况的特征,研究了中国区域气候与热容量变化之间的关系,并用SVD方法研究了北太平洋热容量变化与中国东部夏季气候的耦合关系.结果表明:北太平洋冬季次表层海温按其特征可分为40 m和240 m两类,两者的年代际特征都很明显;北太平洋冬季热容量异常变化与其相似,并与中国东部夏季气候异常有较好的耦合关系,北太平洋中部偏北和东南部地区冬季热容量异常偏高时,中国华南和华北区夏季降水将会偏多,华南区夏季气温将会偏低;黑潮延续体及北太平洋中部偏东地区冬季热容量异常偏高和北美西海岸地区异常偏低时,中国东北和长江流域地区夏季降水将会偏少,东北和华北地区夏季气温将会偏低,其关系有着明显的年代际特征.     

Cross-season relation of the South China Sea precipitation variability between winter and summer

The present study reveals cross-season connections of rainfall variability in the South China Sea (SCS) region between winter and summer. Rainfall anomalies over northern South China Sea in boreal summer tend to be preceded by the same sign rainfall anomalies over southern South China Sea in boreal winter (denoted as in-phase relation) and succeeded by opposite sign rainfall anomalies over southern South China Sea in the following winter (denoted as out-of-phase relation). Analysis shows that the in-phase relation from winter to summer occurs more often in El Niño/La Niña decaying years and the out-of-phase relation from summer to winter appears more frequently in El Niño/La Niña developing years. In the summer during the El Niño/La Niña decaying years, cold/warm and warm/cold sea surface temperature (SST) anomalies develop in tropical central North Pacific and the North Indian Ocean, respectively, forming an east–west contrast pattern. The in-phase relation is associated with the influence of anomalous heating/cooling over the equatorial central Pacific during the mature phase of El Niño/La Niña events that suppresses/enhances precipitation over southern South China Sea and the impact of the above east–west SST anomaly pattern that reduces/increases precipitation over northern South China Sea during the following summer. The impact of the east–west contrast SST anomaly pattern is confirmed by numerical experiments with specified SST anomalies. In the El Niño/La Niña developing years, regional air-sea interactions induce cold/warm SST anomalies in the equatorial western North Pacific. The out-of-phase relation is associated with a Rossby wave type response to anomalous heating/cooling over the equatorial central Pacific during summer and the combined effect of warm/cold SST anomalies in the equatorial central Pacific and cold/warm SST anomalies in the western North Pacific during the mature phase of El Niño/La Niña events.     

2023年夏季我国气候异常特征及成因分析

2023年夏季,我国气候特征整体表现为“温高雨少”,区域性、阶段性高温、旱涝等气象灾害明显。降水的空间分布差异显著,主要多雨区位于我国北方,松花江、海河流域出现严重汛情。生成和登陆台风频数均较常年同期偏少,但北上台风却对京津冀等地造成极其严重的雨涝灾害。2023年夏季我国气温为1961年以来历史次高,北方地区暖异常明显,华北、西北等地区阶段性高温热浪尤为突出。华北、东北地区降水偏多是由不同环流系统造成的。其中,华北南部降水异常偏多主要由7月底至8月初一次极为罕见的天气尺度持续性极端降水过程所致,台风杜苏芮和卡努外围环流与异常偏西、偏北的西太平洋副热带高压相配合,再加上太行山东麓的地形效应是其主要原因。盛夏东北东部异常偏南风引导的水汽输送在整个对流层都异常偏强,造成东北北部和东部降水明显偏多,这一异常环流与初夏巴伦支海海冰密集度减小及盛夏西北太平洋海温异常偏暖均有一定关联。     

东亚夏季经向水汽输送的变异及其对极端降水的影响

东亚夏季降水的异常与水汽输送的变异密切相关。基于1958—2016年资料,研究了夏季东亚季风区经向水汽输送的主要变异特征及其对东亚夏季极端降水的影响。经向水汽输送的第一主变异模态表现出中国东部和西北太平洋上的水汽经向输送呈现反向异常,以年际变化为主。当中国东部向北输送的水汽增强(减弱)而西北太平洋向北输送减弱(增强),则中国东部大范围的极端降水量及频次增加(减少)。该模态与西太(西太平洋)副高西伸(东撤)有关,并主要受到热带中东印度洋海温的影响。第二变异模态以年代际变化为主兼有年际变化,表现在1980年后中国东部及邻近海域上空的经向水汽输送减弱,使得环渤海地区和华南沿海的极端降水量及频次减少而长江上、下游和贵州的极端降水量及频次增加。该模态与西太副高的减弱有关,并受到热带西太海温年代际增温的影响。第三变异模态以年际变化为主兼有年代际变化,反映中国长江以北地区和日本南部及附近区域的经向水汽输送的反相变化结构。长江以北水汽输送减弱(增强),可导致华北、东北的极端降水量及频次减少(增加)和长江下游及江南地区的极端降水量及频次的减少(增加)。该模态主要受欧亚大陆上空中高纬度纬向遥相关波列和热带印太（印度洋太平洋）海温异常的影响。      

中国东部—西太平洋副热带季风和降水的气候特征及成因分析

利用1981—2000年候平均NCEP/NCAR再分析资料和CMAP全球降水资料,分析了从中国东部大陆到西太平洋副热带地区季风和降水季节变化的特征及其与热带季风降水的关系,探讨了季风建立和加强的原因。夏季东亚—西太平洋盛行的西南风开始于江南和西太平洋副热带的春初,并向北扩展到中纬度,热带西南风范围向北扩展的迹象不明显。从冬到夏,中国西部和西太平洋副热带的表面加热季节变化可以使副热带对流层向西的温度梯度反转比热带早,使西南季风在副热带最早开始;从大气环流看,青藏高原东侧低压槽的加强和向东延伸,以及西太平洋副热带高压的加强和向西移动,都影响着副热带西南季风的开始和发展;初夏江南的南风向北扩展与副热带高压向北移动有关,随着高原东侧低压槽向南延伸,槽前的偏南风范围向南扩展。随着副热带季风建立和向北扩展,其最大风速中心前方的低层空气质量辐合和水汽辐合以及上升运动也加强和向北移动,导致降水加强和雨带向北移动。热带季风雨季开始晚,主要维持在热带而没有明显进入副热带,江淮梅雨不是由热带季风雨带直接向北移动而致,而是由春季江南雨带北移而致。在热带季风爆发前,副热带季风区水汽输送主要来自中南半岛北部和中国华南沿海,而在热带季风爆发后,水汽输送来自孟加拉湾和热带西太平洋。     

我国夏季降水与全球气温场的关系

用蒙特卡罗的相关方法研究我国夏季大尺度降水与全球气温场关系，发现我国夏季大尺度降水与全球气温场有密切相关，以同期相关为最密切；除与热带西太平洋、东太平洋等海域有密切相关外，还与欧洲东部、北美洲东北部以及东亚等内陆地区的不同季节气温场有关系。研究还表明，印度洋地区春季气温和北美洲北部及北太平洋西南部夏季气温偏高时，长江中下游夏季易涝。且它们与长江中下游夏季降水的相关均有阶段性，相关密切程度随时间有所增强。     

Onset of southwesterly wind over eastern China and associated atmospheric circulation and rainfall

Using the 5-day averaged data from the National Center for Environmental Prediction/National Center for Atmospheric Research (NCEP/NCAR) reanalysis, and precipitation from rain gauge stations in China for the period 1981–2000, we investigated seasonal variations and associated atmospheric circulation and precipitation of the southwesterly wind over eastern China. The southwesterly wind over eastern China begins earliest over southeastern China and strengthens gradually from spring to the early summer, as it extends northward. The strengthening of the spring southwesterly wind, the tropospheric upward motion, and the convergence of low-level water vapor over southeastern China results in the beginning of the local rainy season. The beginning of the Mei-yu (Plum rainfall) is connected with the northward march of the southwesterly wind. The southwesterly wind reaches the valley of the Yangtze River in the early summer and northern China in the middle summer. This signifies an onset of the large-scale southwesterly wind over eastern China. Accordingly, the rain belt over southeastern China moves to the valley of the Yangtze River in the early summer and to northern China in the middle summer. Moreover, the southerly wind extends southward to the South China Sea from the spring to summer, though it does not stretch from the South China Sea to southeastern China at those times. The strengthening of the southerly wind over southeastern China is associated with a weakening/strengthening of the eastward/westward subtropical tropospheric temperature gradient between southwestern China and the western North Pacific. The developments of a low-pressure system over southwestern China and the subtropical high-pressure system over the western North Pacific may contribute to the strengthening of the southwesterly wind. A northward advance of the high-pressure system favors the southwesterly wind stretching from southeastern China to northern China. The onset of the Indian summer monsoon also strengthens the summer southwesterly wind over eastern China.     

Modulation of the Pacific Decadal Oscillation on the summer precipitation over East China: a comparison of observations to 600-years control run of Bergen Climate Model

Observations show that the summer precipitation over East China often goes through decadal variations of opposite sign over North China and the Yangtze River valley (YRV), such as the “southern flood and northern drought” pattern that occurred during the late 1970s–1990s. In this study it is shown that a modulation of the Pacific Decadal Oscillation (PDO) on the summer precipitation pattern over East China during the last century is partly responsible for this characteristic precipitation pattern. During positive PDO phases, the warm winter sea surface temperatures (SSTs) in the eastern subtropical Pacific along the western coast of North American propagate to the tropics in the following summer due to weakened oceanic meridional circulation and the existence of a coupled wind–evaporation–SST feedback mechanism, resulting in a warming in the eastern tropical Pacific Ocean (5°N–20°N, 160°W–120°W) in summer. This in turn causes a zonal anomalous circulation over the subtropical–tropical Pacific Ocean that induces a strengthened western Pacific subtropical high (WPSH) and thus more moisture over the YRV region. The end result of these events is that the summer precipitation is increased over the YRV region while it is decreased over North China. The suggested mechanism is found both in the observations and in a 600-years fully coupled pre-industrial multi-century control simulations with Bergen Climate Model. The intensification of the WPSH due to the warming in the eastern tropical Pacific Ocean was also examined in idealized SSTA-forced AGCM experiments.     

北太平洋混合层深度异常及其与中国夏季降水的关系

利用GODAS逐月混合层深度(mixed layer depth,MLD)资料和中国160站逐月降水资料,分析了北太平洋MLD多年平均气候及异常特征,进一步研究了其对中国夏季降水年际异常的影响.结果表明:1)北太平洋30 ～ 40°N之间混合层最深,冬、春季明显大于夏、秋季.2)日期线附近的北太平洋中部海域是各季MLD年际异常共同最显著区域;仅夏季MLD年际异常与ENSO存在一定关系;秋、冬和春季MLD还存在明显年代际异常特征.3)当前冬北太平洋西部及中部MLD加深时,次年黄河下游部分地区、黄淮、江淮及长江以南大部分地区(广西南部除外)降水将偏少;河套地区、内蒙东部及东北大部降水可能偏多.     

Analysis of the precipitation and cloudiness associated with COLs occurrence in the Iberian Peninsula

Summary The Iberian Peninsula is one of the regions in the world with higher occurrence of cut-off low systems (COL). The aim of this paper is to analyse the weather events (rainfall and cloudiness layer) associated to COLs in the Iberian Peninsula with tools not previously used: (a) the use of the new multidecadal COLs database developed by Nieto et al (2005) that permit us to study a 41 years period (1958–1998), (b) the checking of the expected weather events (rainfall and cloudiness layer) associated with COLs in a conceptual model (Winkler et al, 2005) and (c) the extensive use of radiosoundings to analyse convective instability in areas inside and close to the COL. Two points of view are used to make the analysis: (1) a source oriented method, when a particular COL is followed and its associated precipitation and cloudiness is analysed over four quadrants in which Iberia was divided and (2) a receptor oriented method, when the precipitation associated to COLs is analysed in given areas, defined by patterns of precipitation. Results reveal that the precipitation and cloudiness patterns associated to COLs in the conceptual model reproduce quite well the main characteristics found over the Iberian Peninsula. The generalized idea that most of the COLs produce intense convective rainfall is show to be misleading. Convective phenomena are important usually when the centre of the COL is located on the Mediterranean region. Most of the rainfall associated with COLs comes from the baroclinic shield; specially in cases located over the west half of the Iberian Peninsula. It is shown that nearly 30% of COLs do not induce any rainfall; most of them located in the southern half of the Peninsula, and mainly during autumn. Only 30% of COLs produce generalized rainfall over the whole analysed territory, being most of them (about 90%) located over the western half of the Iberian Peninsula.     

Regional-scale relationships between aerosol and summer monsoon circulation, and precipitation over northeast Asia

We investigated the regional-scale relationships between columnar aerosol loads and summer monsoon circulation, and also the precipitation over northeast Asia using aerosol optical depth (AOD) data obtained from the 8-year MODIS, AERONET Sun/sky radiometer, and precipitation data acquired under the Global Precipitation Climatology Project (GPCP). These high-quality data revealed the regional-scale link between AOD and summer monsoon circulation, precipitation in July over northeast Asian countries, and their distinct spatial and annual variabilities. Compared to the mean AOD for the entire period of 2001–2008, the increase of almost 40–50% in the AOD value in July 2005 and July 2007 was found over the downwind regions of China (Yellow Sea, Korean peninsula, and East Sea), with negative precipitation anomalies. This can be attributable to the strong westerly confluent flows, between cyclone flows by continental thermal low centered over the northern China and anticyclonic flows by the western North Pacific High, which transport anthropogenic pollution aerosols emitted from east China to aforementioned downwind high AOD regions along the rim of the Pacific marine airmass. In July 2002, however, the easterly flows transported anthropogenic aerosols from east China to the southwestern part of China in July 2002. As a result, the AOD off the coast of China was dramatically reduced in spite of decreasing rainfall. From the calculation of the cross-correlation coefficient between MODIS-derived AOD anomalies and GPCP precipitation anomalies in July over the period 2001–2008, we found negative correlations over the areas encompassed by 105–115°E and 30–35°N and by 120–140°E and 35–40°N (Yellow Sea, Korean peninsula, and East Sea). This suggests that aerosol loads over these regions are easily influenced by the Asian monsoon flow system and associated precipitation.     

北非高压的气候特征及其对中国夏季降水的影响

以北非高压的5个指数为基础，分析了北非高压的气候特征：北非高压强度越强，范围越广，东伸越明显且脊线偏南，反之偏西偏北；北非高压的强弱趋势、南北位置和东西位置具有显著的季节变化，其中5月下旬和6月下旬有两次明显的跳跃，在时间上比西太平洋副高两次北跳提前2-3候。北非高压对中国夏季降水影响主要表现为我国东部地区以长江为界的南北降水具有反相分布特点，西藏高原上东、西部降水存在相反分布。最后，讨论了北非高压与西太平洋副高及东亚环流的关系，发现：两个高压的强度、范围和南北及东西位置的变化趋势基本一致，从西亚到太平洋呈现正、负、正的波列分布特征。这种特征组成了亚洲地区纬向型的遥相关分布，这可能是造成中国夏季降水时空分布的原因之一。     

Characteristics of Subtropical Monsoon and Rainfall over Eastern China and Western North Pacific

Using the NCAR/NCEP (National Center for Atmospheric Research/National Centers for Environmental Prediction) reanalysis and the NOAA Climate Prediction Center's merged analysis of precipitation (CMAP)during 1981-2000, we investigated the seasonal evolution of the southwesterly wind and associated precipitation over the eastern China-subtropical western North Pacific area and its relationship with the tropical monsoon and rainfall, and analyzed the reasons responsible for the onset and development of the wind. It was found that the persistent southwesterly wind appears over southern China and the subtropical western Pacific the earliest in early spring, and then expands southwards to the tropics and advances northward to the midlatitudes. From winter to summer, the seasonal variation of surface heating over western China and the subtropical western Pacific may result in an earlier reversal of the westward tropospheric temperature gradient over the subtropics relative to the tropics, which may contribute to the earliest beginning of the subtropical southwesterly wind. Additionally, the strengthening and eastward expanding of the trough near the eastern Tibetan Plateau as well as the strengthening and westward moving of the western Pacific subtropical high also exert positive influences on the beginning and development of the subtropical southwesterly wind.In early summer,the northward expansion of the southwesterly wind over southern China is associated with a northward shift of the subtropical high, while the southward stretch of the southwesterly wind is associated with a southward stretch of the trough in the eastern side of the plateau. With the beginning and northward expansion of the subtropical southwesterly wind (namely southwest monsoon), convergences of the low-level air and water vapor and associated upward motion in front of the strongest southwesterly wind core also strengthen and move northward, leading to an increase in rainfall intensity and a northward shift of the rain belt. Accordingly, the subtropical rainy season occurs the earliest over southern China in spring, moves northward to the Yangtze-Huaihe River valley in early summer, and arrives in North China in mid summer.Compared with the subtropical rainy season, the tropical rainy season begins later and stays mainly over the tropics, not pronouncedly moving into the subtropics. Clearly, the Meiyu rainfall over the Yangtze-Huaihe River valley in early summer results from a northward shift of the spring rain belt over southern China,instead of a northward shift of the tropical monsoon rain belt. Before the onset of the tropical monsoon,water vapor over the subtropical monsoon region comes mainly from the coasts of the northern Indo-China Peninsula and southern China. After the onset, one branch of the water vapor flow comes from the Bay of Bengal, entering into eastern China and the subtropical western Pacific via southwestern China and the South China Sea, and another branch comes from the tropical western North Pacific, moving northwestward along the west edge of the western Pacific subtropical high and entering into the subtropics.     

华南降水季节演变的年代际变化

利用中国测站的逐日降水资料和NCEP/NCAR再分析资料,分析了近35年华南降水季节演变的年代际变化特征及其相关的大气环流异常特征。华南地区降水季节分布型在1990年代初期发生了年代际转变,其中,华南西部降水在1990年之前为双峰型分布,1990年之后变为以6月为峰值的单峰型分布;华南东部降水在1990年之前是以5月、8月为峰值的弱双峰型分布,1990年之后变为以6月、8月为峰值的显著双峰型分布。华南东、西部降水季节分布的年代际变化分别与华南全区6月降水量的年代际增加以及8月华南东、西部降水显著反相的年代际变化（东多西少）密切相关。1990年之后,大雨及以上强降水事件发生频率的增强是导致上述年代际变化的主要原因。华南6月降水年代际的增强与南海区域的西北太平洋副热带高压（简称西太副高）脊线位置的年代际异常偏南密切相关。7月华南地区降水的年代际增加与西太副高年代际东撤及影响华南地区的热带气旋频数年代际增多有关。8月华南东、西部降水显著反相的年代际变化（东多西少）,一方面受印度洋及南海上空夏季风年代际减弱的影响,使得输送到华南西部的水汽减少,另一方面西太副高的年代际增强并西伸,使得源自副高西南侧的水汽更直接输送至华南东部地区有关;同时也与登陆和影响华南东、西部的热带气旋的年代际增多和减少有关。      

北太平洋夏季大气环流的持续性异常及其对中国天气的影响

对太平洋北部持续性异常的研究表明，正、负异常的形热从发生、发展到消亡的演变过程十分相似，它们都始于东亚及西太平洋区域距平形势的变化，并在北太平洋及东亚地区出现一规则排列的距平异常区域，东亚及整个北半球的大气环流也相应地发生变化。太平洋北部环流的持续性异常对东亚特别是中国夏季的天气异常有重要影响。诊断分析和数值试验表明，夏季太平洋北部大气环流发生持续性异常与太平洋中低纬的海温异常关系密切。     

赤道太平洋对流活动异常对我国夏季降水和气温的影响

利用月平均ＯＬＲ、降水和气温资料,研究了ＥＮＳＯ期间赤道太平洋对流活动与我国夏季降水和气温的关系。结果表明：春季、夏季中、西太平洋对流活动异常与我国夏季江淮地区的降水有密切关系;春季和前一年冬季西太平洋对流活动异常与东北地区夏季降水有显著相关。前一年冬季中、西太平洋对流活动异常与我国降水的显著相关区是不同的,前者为华南、西南地区,后者为东北至内蒙古一带。气温与同期中、西太平洋对流活动的相关不显著。     

赤道太平洋对流活动异常对我国夏季降水和气温的影响

利用月平均ＯＬＲ、降水和气温资料,研究了ＥＮＳＯ期间赤道太平洋对流活动与我国夏季降水和气温的关系。结果表明：春季、夏季中、西太平洋对流活动异常与我国夏季江淮地区的降水有密切关系;春季和前一年冬季西太平洋对流活动异常与东北地区夏季降水有显著相关。前一年冬季中、西太平洋对流活动异常与我国降水的显著相关区是不同的,前者为华南、西南地区,后者为东北至内蒙古一带。气温与同期中、西太平洋对流活动的相关不显著。     

北方雨季中国东部降水异常模态的环流特征及成因分析

根据1958～2011年中国东部（105°E以东）316站逐日降水资料及NCEP/NCAR逐日再分析资料,利用统计分析、物理量诊断等方法,探讨北方雨季（7月11日至8月31日）中国东部降水异常模态及同期、前期的大气环流特征。分析发现,北方雨季中国东部降水异常表现为三个相互独立的降水模态:第一模态为偏西型,当其时间系数为正（负）时,河套地区降水偏多（少）,江淮流域上游降水偏少（多）,南方大部降水偏多（少）;第二模态为北方一致型,当其时间系数为正（负）时,北方降水一致偏多（少）,长江流域降水偏少（多）;第三模态为偏东型,当其时间系数为正（负）时,东北南部至长江中游降水偏多（少）,华东沿海降水偏少（多）。研究发现,造成北方雨季三个降水异常模态的环流特征各不相同:偏西型降水主要受西亚高空副热带西风急流位置南北偏移影响;北方一致型降水主要由东亚-太平洋遥相关波列导致;偏东型降水主要与海陆气压异常对比造成的东亚夏季风变化有关。此外,三个模态与前期环流异常有密切联系。第一模态的正（负）异常由7月上旬200 hPa来自北大西洋的异常波列造成乌拉尔山位势高度负（正）异常和巴尔喀什湖以南位势高度正（负）异常引起。第二模态的正（负）异常与前期7月上旬200 hPa北大西洋上位势高度负（正）异常产生的沿中纬度（高纬度）路径向下游传播的波列有关。第三模态的正（负）异常由春季3月份低层蒙古上空异常的气旋（反气旋）持续至同期造成。     

A decadal shift of summer surface air temperature over Northeast Asia around the mid-1990s

This study identifies a decadal shift of summer surface air temperature （SAT） over Northeast Asia,including southeastern parts of Russia,Mongolia and northern China,around the mid-1990s.The results suggest that the SAT over the Northeast Asia experienced a significant warming after 1994 relative to that before 1993.This decadal shift also extends to northern China,and leads to a warmer summer over Northeast China and North China after the mid-1990s.The decadal warming over Northeast Asia is found to concur with the enhancement of South China rainfall around the mid-1990s.On the one hand,both the Northeast Asian SAT and South China rainfall exhibit this mid-1990s decadal shift only in summer,but not in other seasons.On the other hand,both the Northeast Asian SAT and South China rainfall exhibit this mid-1990s decadal shift not only in the summer seasonal mean,but also in each month of summer （June,July and August）.Furthermore,the decadal warming is found to result from an anticyclonic anomaly over Northeast Asia,which can be interpreted as the response to the increased precipitation over South China,according to previous numerical results.Thus,we conclude that the warming shift of summer Northeast Asian SAT around the mid-1990s was a remote response to the increased precipitation over South China.     

南亚高压与西太平洋副热带高压经纬向位置配置对中国东部夏季降水的影响

利用1951—2016年逐月中国160站降水资料、NCEP/NCAR全球大气再分析资料和NOAA_ERSST_V4海表温度资料,分析了南亚高压与西太平洋副热带高压(西太平洋副高)经、纬向位置的关系及其位置配置对中国东部夏季降水的影响,结果表明:(1)南亚高压与西太平洋副高在纬向上的东西进退存在明显的反相关系,在经向上主要存在一致变化的特征,并依此定义了纬向、经向位置指数。纬向位置指数大(小)表示南亚高压与西太平洋副高纬向上距离远(近),经向位置指数大(小)表示两高压经向位置均趋于偏北(南);(2)纬向位置指数与我国华北、华南沿海地区降水呈显著正相关,而与长江中下游、东北北部地区降水呈显著负相关;经向位置指数与我国华北、东北南部地区降水呈显著正相关,而与我国江南、华南地区降水呈显著负相关;(3)南亚高压与西太平洋副高的经向、纬向位置指数与关键海区的前期春季、同期夏季海表温度均有显著的相关,热带太平洋-印度洋、北印度洋、中东太平洋前期春季、同期夏季海表温度与南亚高压东脊点呈显著正相关,与南亚高压脊线及西太平洋副高西脊点均呈显著负相关,而北太平洋海表温度主要与西太平洋副高脊线呈显著正相关。