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1.
Alice Favre Bruce Hewitson Mark Tadross Christopher Lennard Ruth Cerezo-Mota 《Climate Dynamics》2012,38(7-8):1473-1487
The characteristics of Southern Cut-off Lows (CoLs) are studied for the period 1979–2008. The systematic identification of CoLs is realized by applying an original automated scheme using mean daily geopotential height and air temperature at 500?hPa NCEP-DOE II Reanalysis data. From closed lows’ trajectories established from the Equator to the polar jet stream, extratropical lows are analyzed and the stage of cut-off is defined as a secluded low presenting a cold core. From 4,843 cases the general CoL features are presented and confirm several previous results such as the geographic distribution which shows that they are more frequent in the latitudinal band contained between 20°S and 45°S and in close proximity to the continents. On a seasonal time scale, CoLs are more numerous from late summer to autumn, with a maximum of frequency in March/April. In winter (June–July–August), they are fewer but deeper than during the rest of the year. In the median domain (~32.5°S), the annual cycle of the frequency is bimodal and present two peaks during transitional seasons. In this zone, the seasonal cycle varies in accordance with the Semiannual Oscillation. Thereby, when the meridional gradient of temperature/pressure is reinforced between mid and high latitudes, CoLs are more frequent in the median domain. Over the period 1979–2008, the annual CoLs’ frequency exhibits a positive trend of about 25%. This increase is associated with a widening of the latitudinal domain of occurrence equatorward as well as poleward. The trend is linked with an abrupt positive shift in the number of CoLs’ generation between 1998 and 1999. The geographical distribution of CoLs frequency varies significantly in accordance with El Ni?o Southern Oscillation with more CoL’s at lower (higher) latitudes during La Ni?a (El Ni?o) events, principally in the Southern Pacific. 相似文献
2.
The capability of a current state-of-the-art regional climate model for simulating the diurnal and annual cycles of rainfall over a complex subtropical region is documented here. Hourly rainfall is simulated over Southern Africa for 1998–2006 by the non-hydrostatic model weather research and forecasting (WRF), and compared to a network of 103 stations covering South Africa. We used five simulations, four of which consist of different parameterizations for atmospheric convection at a 0.5 × 0.5° resolution, performed to test the physic-dependency of the results. The fifth experiment uses explicit convection over tropical South Africa at a 1/30° resolution. WRF simulates realistic mean rainfall fields, albeit wet biases over tropical Africa. The model mean biases are strongly modulated by the convective scheme used for the simulations. The annual cycle of rainfall is well simulated over South Africa, mostly influenced by tropical summer rainfall except in the Western Cape region experiencing winter rainfall. The diurnal cycle shows a timing bias, with atmospheric convection occurring too early in the afternoon, and causing too abundant rainfall. This result, particularly true in summer over the northeastern part of the country, is weakly physic-dependent. Cloud-resolving simulations do not clearly reduce the diurnal cycle biases. In the end, the rainfall overestimations appear to be mostly imputable to the afternoon hours of the austral summer rainy season, i.e., the periods during which convective activity is intense over the region. 相似文献
3.
采用TRMM(Tropical Rainfall Measuring Mission)降水和云特征数据集,对南海2001年1月至2012年3月不同回波顶高对流系统的垂直结构、表面降雨率、数量时空分布的季节变化进行统计分析。结果表明:①浅对流、较深对流、深对流大于20dBz的回波区分别分布在4~8km、4~10km、4~14km之间;浅对流20dBz回波顶高的频率峰值为9km;冬季,较深对流、深对流20dBz回波顶高的频率峰值分别为13km、14.5km,其余季节偏高分别为14.5km、16km。②较深对流和深对流是南海地区面积平均降雨率较强的2种主要的降水系统;夏秋两季,较深对流的降雨率大于深对流;冬春两季,深对流的降雨率大于较深对流。③较深对流、深对流出现频次最少的季节为冬季,浅对流则为春季。④浅对流偏向于出现在12°N以南;深对流偏向于出现在12°N以北;较深对流在冬春季节集中在12°N以南,夏秋季节横贯南海。⑤夏秋两季在南海北部出现气旋性辐合上升的差异中心,南海中南部的西南水汽输送差异与700hPa以下水汽的辐合差异,是较深对流在夏秋两季比冬春两季带来更强降雨率的主要原因。 相似文献
4.
Winter Asia Jetstream and Seasonal Precipitation in East China 总被引:9,自引:0,他引:9
WinterAsiaJetstreamandSeasonalPrecipitationinEastChina¥LitrngPingde(梁平德)andLiuAixia(刘爱霞)WinterAsiaJetstreamandSeasonalPrecipi?.. 相似文献
5.
利用Lamb-Jenkinson大气环流分型方法,对西江流域1971—2015年逐日平均850 hPa和500 hPa高度场进行环流客观分型,分析流域降水天气环流型出现概率及主导环流型变化特征,探讨主导环流型对西江流域总面雨量和子流域面雨量的贡献率及环流型配置与降水的关系。结果表明:当850 hPa为西南风型、500 hPa为西风型时,流域出现降水天气的概率最大;850 hPa气旋型和500 hPa西风型对年总面雨量和各子流域面雨量的贡献率均为最大,且对东部子流域面雨量的贡献率大于西部子流域,850 hPa南风型与500 hPa反气旋型的环流配置是西部子流域秋季降水偏多的主导环流型配置;春季850 hPa气旋型与500 hPa西风型、夏季850 hPa气旋型与500 hPa西风型、秋季850 hPa南风型与500 hPa反气旋型、冬季850 hPa西南风型与500 hPa西风型的环流配置时,出现强降水天气的概率分别为18.7%,21.1%,4.0%和2.0%,即夏季最大,其次为春季,冬季最小。近45年,850 hPa气旋型、500 hPa西风型对流域年总面雨量的贡献率呈增加趋势,是西江流域面雨量呈偏多趋势的主导环流型。 相似文献
6.
近50年来中国夏季降水及水汽输送特征研究 总被引:15,自引:3,他引:12
利用1951-2006年中国448站夏季降水资料、NCEP/NCAR VersionⅠ的再分析资料,研究了近50年来中国夏季降水年代际变化特征及其分区,并从季风性水汽输送的变化角度出发,讨论了影响中国一些主要地区降水变化的可能机制.研究发现:(1)从总体上来说,自1951年至今,中国夏季降水存在3个突变时段,即1956-1960年,1980年前后以及1993年以后.且90°E以东突变后的主要变化特征都是多雨区由北向南传播,而90°E以西则是多雨区由南向北传播;2)近56年来就110°E以东的中国东部夏季降水而言,1980年以后多雨区由华北南移到长江中下游,又于1993年以后由长江中下游继续南移至华南;3)中国东部各地区降水和850 hpa风场、整层水汽输送场的相关分布一致表明,中国110°E以东各降水区以南为来自偏东偏南的季风性异常水汽输送,而以北为来自偏北风和相应的异常水汽输送,两者在降水区汇合造成风和水汽输送异常辐合.因而,西太平洋副热带高压南侧的东南季风及其异常水汽输送、北方冷槽的偏北风及其异常水汽输送是中国东部夏季降水异常的主要成员,这和一般认为的这些地区降水异常来自孟加拉湾的季风性异常水汽输送的观点不同,需要作进一步研究.总之,对于中国东部旱涝的形成,应该重点注意来自西北太平洋副热带高压西侧的直接或间接经南海到达的异常四南季风性水汽输送. 相似文献
7.
Spatial and temporal variability of summer rainfall over Ethiopia from observations and a regional climate model experiment 总被引:2,自引:1,他引:1
T. Zeleke F. Giorgi G. Mengistu Tsidu G. T. Diro 《Theoretical and Applied Climatology》2013,111(3-4):665-681
The spatial and temporal variability of rainfall over Ethiopia during the summer (JJAS) season is studied using observations (both station and satellite based) and model simulation data. The simulation dataset is generated using the fourth version of the International Center for Theoretical Physics Regional Climate Model (RegCM4) for the period 1989–2005. Ethiopia is first divided into 12 homogeneous regions using criteria including rotated empirical orthogonal function (REOF), spatial correlation, seasonal cycles, and topographical features. Spatially averaged observed and simulated rainfall time series are then generated and analyzed for each region. Standardized rainfall anomalies of the observations and the simulated data are highly correlated over the northern, western, northeastern, central, and southwestern regions, while a weak correlation is found over the border regions of the country. The dominant modes of rainfall variability are identified using REOF, while time–frequency variations of different dominant modes are described by wavelet analysis. The first leading patterns of rainfall and upper wind (averaged between 100 and 300 hPa) are highly correlated and exhibit similar features between simulation and observations over the northern, western, southwestern, and eastern regions of Ethiopia. The second loading pattern of rainfall and the first loading pattern of low-level wind (averaged between 850 and 1,000 hPa) exhibit a dipole structure across the southwestern and northeastern regions of the country. The dominant signals in the first rotated principal component (RPC) of rainfall and upper level wind fields show a period of 4–5 and 2–3 years, while the dominant signals in the second RPC show a period of 2–3 years at a 0.05 significance level. The correlations of significant RPCs across gauge, gridded, and model rainfall fields with that of low and upper level winds show the presence of a significant relationship (correlation exceeding ~0.6). Overall, the RegCM4 shows a good performance in simulating the spatial and temporal variability of precipitation over Ethiopia. 相似文献
8.
长江流域夏季不同强度降水日数的时空变化特征 总被引:2,自引:1,他引:1
利用长江流域56个站点1957—2009年夏季逐日降水资料、NCEP/NCAR再分析资料以及Hadley海表温度资料,分析了长江流域夏季不同强度降水日数的时空变化及其相关的海气异常型。结果表明:(1)近53 a来,长江流域夏季大到暴雨日数占总降水日数的比率呈明显增加趋势,而中小雨日数占总降水日数的比率呈明显减少趋势。(2)长江流域夏季不同强度降水日数的变化及其相应的海气异常型表现为明显不同的特征。当前期春季海温距平场表现为典型的东部型El Nino分布形态,500 h Pa位势高度场呈现出"+-+"的经向PJ波列,西北太平洋副热带高压偏强,位置偏南偏西,中高纬地区乌拉尔山和鄂霍次克海地区出现双阻塞形势,南半球澳大利亚高压异常偏强,越赤道气流偏强,在30°N附近200 h Pa纬向西风急流异常偏强,850 h Pa风场在东亚上空经向方向上呈现出明显的反气旋—气旋—反气旋系统相间分布的特征时,有利于长江流域夏季大到暴雨降水日数偏多。 相似文献
9.
Satellite-derived rainfall estimates and the ERA-Interim reanalysis are used to better understand cold air surge/precipitation interactions and to identify the implications for rainfall variability in the Sahel and tropical Africa on synoptic to seasonal timescales. At the synoptic timescale, cold air surges are associated with cold conditions over the eastern Sahara throughout the year due to the eastward passage of surface low pressure systems over the Mediterranean and the subsequent ridging over northern Africa. Rainfall decreases over central and eastern Africa approximately 4–5 days after the cold air first arrives in northeastern Africa. These precipitation anomalies persist for 4 or more days. At the seasonal timescale, a significant relationship between eastern Saharan low-level temperatures and rainfall in the Sahel and tropical Africa is identified, with colder conditions associated with reduced convection on the northern flank of the primary convergence zone, and vice versa. During boreal winter, the anomalous rainfall occurs over tropical Africa (0°N–8°N). During the summer, rainfall anomalies associated with cold air surges occur over the Sahel (10°N–16°N). These relationships are mediated by anomalous anticyclonic flow over northwestern Africa and western Europe. The analysis shows that cold air surges are significantly associated with summertime cooling over the Sahara, but less so during the winter. 相似文献
10.
Zhi-Yong Yin Yunlong Cai Xinyi Zhao Xiaoling Chen 《Theoretical and Applied Climatology》2009,97(3-4):205-218
In this study, we investigated spatial and temporal variation patterns of persistent moderate-to-heavy rainfall events in Guizhou Province of southwest China during 1951–2004. We first performed conventional frequency analysis using the annual maximum daily series at 36 weather stations fit to log-normal distribution curves. Then, we examined the frequencies of moderate-to-heavy rainfall events (>?=?20 mm/day) and persistent rainfall events (10–day running sum >?=?100 mm) during the summer season (June through August). Using principal component analysis, we identified various spatial patterns of the rainfall regime and macroscale atmospheric conditions that influence these patterns. It was found that a minor mode of variation in the 500 hPa geopotential height anomaly field over East Asia (the third principal component) had a very good relationship to the dominant regional precipitation regime (Spearman’s correlation coefficient?=?–0.623). This mode of circulation represents the N–S variation of the upper-air pressure gradients over East Asia. During its positive phase, the pressure gradient south of 40°N is reduced and accompanied by a ridge over the East China coast, while the pressure gradient north of this latitude is enhanced. Correspondingly, the study region experiences fewer persistent moderate-to-heavy rainfall events. In its negative phase, the pattern in the 500 hPa geopotential height anomaly field is reversed and the study region experiences more persistent moderate-to-heavy rainfall events. This circulation mode is related to both East Asian and Indian summer monsoons. It is also associated with the northward intrusion of the West Pacific subtropical high, the size of the circumpolar vortex over the Pacific, and the impact of the Tibetan Plateau. 相似文献
11.
Xuan Thanh Pham Bernard Fontaine Nathalie Philippon 《Theoretical and Applied Climatology》2010,99(1-2):105-113
The summer monsoon onset over southern Vietnam is determined through a new criterion based on both in situ daily rainfall at six selected stations provided by the Institute of Meteorology and Hydrology, Vietnam, and the zonal component of the wind at 1,000 hPa from the National Center for Environmental Prediction/Department of Energy Reanalysis 2. Over the period 1979–2004, the summer monsoon onset mean date is on 12 May, with a standard deviation of 11.6 days. The temporal and spatial structures of the atmospheric conditions prevailing during the onset period are detailed. Clear changes are seen in the zonal wind (strengthened over the Bay of Bengal and changed from negative to positive over South Vietnam) and in convection (deeper), in association with an intensification of the meridional gradients of sea level pressure at 1,000 hPa and of moist static energy at 2 m over Southeast Asia. The predictability of onset dates is then assessed. Cross-validated hindcasts based upon four predictors linked to robust signals in the atmospheric dynamics are then provided. They are highly significant when compared to observations (56% of common variance). Basically, late (early) onsets are preceded in March–April by higher (lower) sea level pressure over the East China Sea, stronger (weaker) southeasterly winds over southern Vietnam, decreasing (increasing) deep convection over the Bay of Bengal, and the reverse situation over Indonesia (120–140°E, 0–10°S). 相似文献
12.
In this paper, we attempt to highlight the relevance of cutoff low systems (CoLs) to large-scale heavy precipitation events within the Alpine region which often lead to catastrophic flooding. The main results of this study are (1) a detailed climatology (1971–1999) of CoLs for the European region, (2) contribution of CoLs to extreme precipitation events in the European Alpine region, (3) identification of regions within the European Alps most affected by extreme precipitation caused by CoLs, and (4) identification of regions where presence of CoLs is related to extreme precipitation in the Alpine region. The findings of this paper suggest that CoLs have a significant correlation with extreme precipitation events and strongly influence the climate of the Alpine region. The total contribution of CoLs to large-scale heavy precipitation events ranges between 20 and 95 % and is most pronounced in the northern and eastern parts of the Alps. More than 80 % of the events occur in the summer season. The area around the Alps and West of Spain (over the Atlantic Ocean) is the most affected region. The location of the center of CoLs that affect the Alpine region most occur on the northern and southern sides of the Alpine ridge. 相似文献
13.
Using daily observational rainfall data covered 194 stations of China from 1961 to 1995 and NCEP model analyzed pentad precipitation data of global grid point from 1979 to 1997,the distribution of onset date of rainy season over Asian area from spring to summer is studied in this paper.The analyzed results show that there exist two stages of rainy season onset over East Asian region from spring to summer rainy season onset accompanying subtropical monsoon and tropical monsoon respectively.The former rain belt is mainly formed by the convergence of cold air and the recurred southwesterly flow from western part of subtropical high and westerly flow from the so-called western trough of subtropical region occurring during winter to spring over South Asia.The latter is formed in the process of subtropical monsoon rain belt over inshore regions of South China Sea originally coming from south of Changjiang (Yangtze) River Basin advancing with northward shift of subtropical high after the onset of tropical monsoon over South China Sea.The pre-flood rainy season over South China region then came into mature period and the second peak of rainfall appeared.Meiyu,the rainy season over Changjiang-Huaihe River Basin and North China then formed consequently.The process of summer tropical monsoon onset over South China Sea in 1998 is also discussed in this paper.It indicated that the monsoon during summer tropical monsoon onset over South China Sea is the result of the westerly flow over middle part of South China Sea,which is from the new generated cyclone formed in north subtropical high entering into South China Sea,converged with the tropical southwesterly flow recurred by the intensified cross-equatorial flow. 相似文献
14.
Based on daily precipitation data from 524 meteorological stations in China during the period 1960–2009, the climatology and the temporal changes (trends, interannual, and decadal variations) in the proportion of seasonal precipitation to the total annual precipitation were analyzed on both national and regional scales. Results indicated that (1) for the whole country, the climatology in the seasonal distribution of precipitation showed that the proportion accounted for 55 % in summer (June–August), for around 20 % in both spring (March–May) and autumn (September–November), and around 5 % in winter (December–February). But the spatial features were region-dependent. The primary precipitation regime, “summer–autumn–spring–winter”, was located in central and eastern regions which were north of the Huaihe River, in eastern Tibet, and in western Southwest China. The secondary regime, “summer–spring–autumn–winter”, appeared in the regions south of the Huaihe River, except Jiangnan where spring precipitation dominated, and the southeastern Hainan Island where autumn precipitation prevailed. (2) For the temporal changes on the national scale, first, where the trends were concerned, the proportion of winter precipitation showed a significantly increasing trend, while that of the other three seasons did not show any significant trends. Second, for the interannual variation, the variability in summer was the largest among the four seasons and that in winter was the smallest. Then, on the decadal scale, China experienced a sharp decrease only in the proportion of summer precipitation in 2000. (3) For the temporal changes on the regional scale, all the concerned 11 geographic regions of China underwent increasing trends in the proportion of winter precipitation. For spring, it decreased over the regions south of the Yellow River but increased elsewhere. The trend in the proportion of summer precipitation was generally opposite to that of spring. For autumn, it decreased over the other ten regions except Inner Mongolia with no trend. It is noted that the interannual variability of precipitation seasonality is large over North China, Huanghuai, and Jianghuai; its decadal variability is large over the other regions, especially over those regions south of the Yangtze River. 相似文献
15.
M. Azhar Ehsan In-Sik Kang Mansour Almazroui M. Adnan Abid Fred Kucharski 《Climate Dynamics》2013,41(9-10):2697-2709
Changes over the twentieth century in seasonal mean potential predictability (PP) of global precipitation, 200 hPa height and land surface temperature are examined by using 100-member ensemble. The ensemble simulations have been conducted by using an intermediate complexity atmospheric general circulation model of the International Center for Theoretical Physics, Italy. Using the Hadley Centre sea surface temperature (SST) dataset on a 1° grid, two 31 year periods of 1920–1950 and 1970–2000 are separated to distinguish the periods of low and high SST variability, respectively. The standard deviation values averaged for the (“Niño-3.4”; 5°S–5°N, 170°W–120°W) region are 0.71 and 1.15 °C, for the periods of low and high SST variability, respectively, with a percentage change of 62 % during December–January–February (DJF). The leading eigenvector and the associated principal component time series, also indicate that the amplitude of SST variations have positive trend since 1920s to recent years, particularly over the El Niño Southern Oscillation (ENSO) region. Our hypothesis states that the increase in SST variability has increased the PP for precipitation, 200 hPa height and land surface temperature during the DJF. The analysis of signal and noise shows that the signal-to-noise (S/N) ratio is much increased over most of the globe, particularly over the tropics and subtropics for DJF precipitation. This occurs because of a larger increase in the signal and at the same time a reduction in the noise, over most of the tropical areas. For 200 hPa height, the S/N ratio over the Pacific North American (PNA) region is increasing more than that for the other extratropical regions, because of a larger percentage increase in the signal and only a small increase in noise. It is also found that the increase in seasonal mean transient signal over the PNA region is 50 %, while increase in the noise is only 12 %, during the high SST variability period, which indicates that the increase in signal is more than the noise. For DJF land surface temperature, the perfect model notion is utilized to confirm the changes in PP during the low and high SST variability periods. The correlation between the perfect model and the other members clearly reveal that the seasonal mean PP changed. In particular, the PP for the 31 years period of 1970–2000 is higher than that for the 31 years period of 1920–1950. The land surface temperature PP is increased in northern and southern Africa, central Europe, southern South America, eastern United States and over Canada. The increase of the signal and hence the seasonal mean PP is coincides with an increase in tropical Pacific SST variability, particularly in the ENSO region. 相似文献
16.
ON THE PROCESS OF SUMMER MONSOON ONSET OVER EAST ASIA 总被引:6,自引:0,他引:6
Using daily observational rainfall data covered 194 stations of China from 1961 to 1995 andNCEP model analyzed pentad precipitation data of global grid point from 1979 to 1997,thedistribution of onset date of rainy season over Asian area from spring to summer is studied in thispaper.The analyzed results show that there exist two stages of rainy season onset over East Asianregion from spring to summer rainy season onset accompanying subtropical monsoon and tropicalmonsoon respectively.The former rain belt is mainly formed by the convergence of cold air and therecurred southwesterly flow from western part of subtropical high and westerly flow from the so-called western trough of subtropical region occurring during winter to spring over South Asia.Thelatter is formed in the process of subtropical monsoon rain belt over inshore regions of South ChinaSea originally coming from south of Changjiang (Yangtze) River Basin advancing with northwardshift of subtropical high after the onset of tropical monsoon over South China Sea.The pre-floodrainy season over South China region then came into mature period and the second peak of rainfallappeared.Meiyu,the rainy season over Changjiang-Huaihe River Basin and North China thenformed consequently.The process of summer tropical monsoon onset over South China Sea in 1998is also discussed in this paper.It indicated that the monsoon during summer tropical monsoononset over South China Sea is the result of the westerly flow over middle part of South China Sea,which is from the new generated cyclone formed in north subtropical high entering into SouthChina Sea,converged with the tropical southwesterly flow recurred by the intensified cross-equatorial flow. 相似文献
17.
利用MPI-ESM-LR模式RCP8.5情景下海冰浓度、降水、海表面温度、500 hPa位势高度和850 hPa风场等数据,对比分析了一次北极海冰突变前后春季海冰与东亚夏季降水关系的差异,并探究其可能成因。结果表明:1)北极海冰突变导致北极海冰浓度(Sea Ice Concentration,SIC)和ENSO对东亚夏季降水的影响均发生变化。突变前SIC和ENSO共同影响降水年际变化;突变后ENSO主导降水EOF的第一模态,SIC主导降水EOF的第二模态;2)北极海冰突变前,ENSO和SIC通过500 hPa经向波列,影响整个东亚地区的850 hPa风场,最终导致三极子型降水模态。突变后,ENSO通过500 hPa经向波列,影响华南地区的850 hPa风场,导致降水的偶极子空间模态,从而主导降水EOF的第一模态;同时SIC通过东亚地区500 hPa纬向波列,影响北方850 hPa风场,最终主导降水EOF的第二模态。3)北极海冰突变后,ENSO和SIC对东亚夏季降水的影响存在区域差异。北极海冰突变前,ENSO和SIC共同影响南北方降水;北极海冰突变后,SIC主要影响北方降水,ENSO主要影响南方降水。 相似文献
18.
北半球环状模(NAM)、东北冷涡与前汛期华南旱涝 总被引:11,自引:3,他引:11
利用中国气象局国家气象信息中心提供的1951-2004年全国160站月平均降水资料和欧洲中心提供的ERA-40再分析资料,对近50年华南前汛期降水、东北冷涡、前期北半球环状模和海温的关系进行了统计分析,定义了一个前汛期东北冷涡强度指数(NECVI),结果表明:前汛期东北冷涡强度与华南降水存在显著的正相关,东北冷涡强年,华南降水偏多,前期2-3月份北半球环状模(NAM)偏弱;反之,东北冷涡偏弱年,华南降水偏少,前期2-3月份NAM偏强。此外,前汛期东北冷涡的强度和前期的中国近海海温存在显著的负相关,前期的NAM和中国近海海温的异常可以作为前汛期东北冷涡异常的一个前兆信号,进而为华南地区前汛期降水异常的预测提供参考依据。 相似文献
19.
P. P. Sreekala S. V. Bhaskara Rao M. S. Arunachalam C. Harikiran 《Theoretical and Applied Climatology》2014,118(1-2):107-114
Using the NCEP/NCAR reanalysis wind and temperature data (1948–2011) and India Meteorological Department (IMD) rainfall data, a long-term trend in the tropical easterly jet stream and its effect on Indian summer monsoon rainfall has been explained in the present study. A decreasing trend in zonal wind speed at 100 mb (maximum decrease), 150 mb, and 200 mb (minimum) is observed. The upper-level (100, 150, and 200 mb) zonal wind speed has been correlated with the surface air temperature anomaly index (ATAI) in the month of May, which is taken as the difference in temperature anomaly over land (22.5°N–27.5°N, 80°E–90°E) and Ocean (5°S–0°S, 75°E–85°E). Significant high correlation is observed between May ATAI and tropical easterly jet stream (TEJ) which suggests that the decreasing land–sea temperature contrast could be one major reason behind the decreasing trend in TEJ. The analysis of spatial distribution of rainfall over India shows a decreasing trend in rainfall over Jammu and Kashmir, Arunachal Pradesh, central Indian region, and western coast of India. Increasing trend in rainfall is observed over south peninsular and northeastern part of India. From the spatial correlation analysis of zonal wind with gridded rainfall, it is observed that the correlation of rainfall is found to be high with the TEJ speed over the regions where the decreasing trend in rainfall is observed. Similarly, from the analysis of spatial correlation between rainfall and May ATAI, positive spatial correlation is observed between May ATAI and summer monsoon rainfall over the regions such as south peninsular India where the rainfall trend is positive, and negative correlation is observed over the places such as Jammu and Kashmir where negative rainfall trend is observed. The decreased land–sea temperature contrast in the pre-monsoon month could be one major reason behind the decreased trend in TEJ as well as the observed spatial variation in the summer monsoon rainfall trend. Thus, the study explained the long-term trend in TEJ and its relation with May month temperature over the Indian Ocean and land region and its effect on the trend and spatial distribution of Indian summer monsoon rainfall. 相似文献
20.
采用中国地面气象观测站2 474个站的降水资料以及NCEP/NCAR再分析资料,利用经验正交函数展开、相关分析和小波分析等方法,探讨了中国东部夏季主要降水型与春季高原大气视热源之间的可能相关特征,并初步分析了前春高原大气加热对东部夏季降水异常分布的影响机制。降水EOF分析表明,中国东部夏季降水主要分为:华南—江淮型和长江中下游型;相关和周期分析表明,300 hPa和400 hPa高原南部地区、500 hPa高原北部地区视热源与华南—江淮降水型之间相关显著,3个区域视热源均与华南降水呈负相关,且与江淮降水呈正相关;200 hPa高原偏北地区、500 hPa高原东部地区视热源与长江中下游地区降水呈负相关,而500 hPa高原西部地区视热源则与长江中下游降水呈正相关关系。以上春季高原不同高度关键区域的视热源可为预报夏季降水提供重要判据;从视热源与各个降水中心的相关特征可见,春季高原上空视热源加热场结构会影响中国东部夏季雨带南北位置的分布情况。由春至夏高原加热的"气泵"作用,使得由孟加拉湾和南海地区水汽输送经高原东部地区后,折向东输送至中国大陆东部地区。加热偏强时,水汽向北输送分量加强,雨带偏北,降水"南少北多",反之亦然。 相似文献