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1.
青藏高原大气热源和冬春积雪与中国东部降水的年代际变化关系 总被引:25,自引:0,他引:25
利用NCEP 1950—2004年逐日再分析资料,采用倒算法,对青藏高原大气热源的长期变化进行了计算,结果发现,青藏高原及附近地区上空大气春夏季热源在过去50年里,尤其是最近20年,表现为持续减弱的趋势。而1960—2004年青藏高原50站的冬春雪深却出现了增加,尤其是春季雪深在1977年出现了由少到多的突变。用SVD方法对高原积雪和高原大气热源关系的分析表明,二者存在非常显著的反相关关系,即高原冬春积雪偏多,高原大气春夏季热源偏弱。高原大气春夏季热源和中国160站降水的SVD分析表明,高原大气春夏季热源和夏季长江中下游降水呈反相关,与华南和华北降水呈正相关;而高原冬春积雪和中国160站降水的SVD分析显示,高原冬春积雪和夏季长江流域降水呈显著正相关,与华南和华北降水呈反相关。在年代际尺度上,青藏高原大气热源和冬春积雪与中国东部降水型的年代际变化(南涝北旱)有很好的相关。最后讨论了青藏高原大气热源影响中国东部降水的机制。青藏高原春夏季热源减弱,使得海陆热力差异减小,致使东亚夏季风强度减弱,输送到华北的水汽减少,而到达长江流域的水汽却增加;同时,高原热源减弱,使得副热带高压偏西,夏季雨带在长江流域维持更长时间。导致近20年来长江流域降水偏多,华北偏少,形成"南涝北旱"雨型。高原冬春积雪的增加,降低了地表温度,减弱了地面热源,并进而使得青藏高原及附近地区大气热源减弱。 相似文献
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青藏高原冬春积雪和地表热源影响亚洲夏季风的研究进展 总被引:2,自引:0,他引:2
青藏高原冬春积雪和地表热源的气候效应是青藏高原气候动力学的两个重要内容。大量资料分析和数值试验研究均表明这两个因子对亚洲季风有一定的预测意义,本文对此做了比较系统的回顾和总结,并进一步比较了青藏高原积雪和地表热源影响东亚和南亚夏季降水的异同。结果表明,东亚夏季降水在年际和年代际尺度上均存在"三极型"和"南北反相"型的空间分布特征,高原春季地表热源在年代际和年际尺度上主要影响东亚夏季降水"三极型"模态;在年代际尺度上它是中国东部出现"南涝北旱"格局的重要原因,而高原冬季积雪的作用相反。另一方面,高原冬季积雪在年际和年代际尺度上对印度夏季风降水的预测效果均要优于高原地表热源。无论是空间分布还是时间演变特征,高原冬季积雪与春季地表热源整体上均无统计意义上的显著联系。不断完善高原地面观测网和改进模式在高原地区的模拟性能,将是进一步深入理解高原积雪和地表热源影响亚洲季风物理过程和机制的关键所在。 相似文献
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青藏高原冬春季积雪异常对中国春夏季降水的影响 总被引:27,自引:3,他引:27
利用1956年12月~1998年12月共42a,青藏高原及其附近地区78个积雪观测站的雪深和我国160站月降水的距平资料,分析了其气候特征,并用SVD方法分析了冬春季积雪异常与春夏季我国降水异常的关系。用区域气候模式RegCM2模拟了青藏高原积雪异常的气候效应并检验了诊断分析的结果。分析表明,雪深异常,尤其是冬季雪深异常是影响中国降水的一个因子。研究证明,高原冬季雪深异常对后期中国区域降水的影响比春季雪深异常的影响更为重要。数值模拟的结果表明,高原雪深和雪盖的正异常推迟了东亚夏季风的爆发日期,减弱了季风强度,造成华南和华北降水减少,而长江和淮河流域降水增加。冬季雪深异常比冬季雪盖异常和春季雪深异常对降水的影响更为显著。机理分析指出,高原及其邻近地区的积雪异常首先通过融雪改变土壤湿度和地表温度,从而改变了地面到大气的热量、水汽和辐射通量。由此所引起的大气环流变化又反过来影响下垫面的特征和通量输送。在湿土壤和大气之间,这样一种长时间的相互作用是造成后期气候变化的关键过程。与干土壤和大气的相互作用过程有本质差别。 相似文献
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青藏高原积雪与亚洲季风环流年代际变化的关系 总被引:12,自引:1,他引:12
利用高原测站的月平均雪深资料和NCEP/NCAR再分析资料,分析了20世纪70年代末以来,青藏高原积雪的显著增多与亚洲季风环流转变的联系。研究表明,高原南侧冬春季西风的增强及西风扰动的活跃是造成青藏高原冬春积雪显著增多的主要原因,高原积雪的增多与亚洲夏季风的减弱均是亚洲季风环流转变的结果;20世纪70年代末以来,夏季华东降水的增多、华南降水的减少及华北的干旱化与青藏高原冬春积雪增多及东亚夏季风的减弱是基本同步的,高原冬春积雪与华东夏季降水的正相关、与华北及华南夏季降水的负相关主要是建立在年代际时间尺度上,因此,高原积雪与我国夏季降水关系的研究应以亚洲季风环流的年代际变化为背景。 相似文献
5.
针对青藏高原热力强迫作用对东亚夏季风强度、南海夏季风爆发早晚、南海周边区域旱涝的影响,以及在全球变暖背景下其对降水格局的影响等科学研究进行了总结回顾,并就青藏高原热力作用对南海周边区域夏季气候的影响科学问题进行了探讨。研究表明,高原冬春积雪异常通过影响雪盖反照率、改变辐射平衡和通过积雪-水文效应改变土壤湿度两个途径来影响东亚夏季风;通过改变大陆-海洋经向热力对比影响南海季风爆发早晚;通过改变西太平洋副高位置和季风环流变化来影响华南和长江流域夏季降水的分布。在全球变暖背景下,青藏高原感热加热的减弱可能对降水年代际“南涝北旱”格局的形成具有重要贡献。随着全球变暖减缓,青藏高原中部和东部的感热呈现出复苏态势,“南涝北旱”的降水格局分布在将来有可能被打破。 相似文献
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青藏高原热力强迫对中国东部降水和水汽输送的调制作用 总被引:12,自引:1,他引:11
从4个方面综述了有关青藏高原大地形热力“驱动”对中国东部雨带和水汽输送特征及其年代际变化的影响作用的研究进展:(1)中国三阶梯大地形热力过程变化与季风雨带季节演进;(2) 青藏高原地-气过程热力“驱动”及其季风水汽输送结构;(3) 青藏高原积雪冷源对中国东部水汽输送结构及其雨带分布的影响;(4) 青藏高原视热源变化与雨带年代际变化相关特征及其可能调制。其主要研究结论是:(1)中国西部高原特殊三阶梯大地形结构强化了海-陆热力差异,尤其是高原大地形使地-气热力差异季节变化有由青藏高原向东北方向大地形区域延伸变化趋势,且其与季风雨带由东南沿海移向西北朝青藏高原与黄土高原边缘同步演进,两者似乎存在类似季节内演进的一种“动态的吸引”。(2)中国东部雨带时空变化特征和季风强弱变化趋势均与青藏高原热源强弱异常变化相对应。青藏高原热源异常影响低纬度海洋向陆地的水汽传输路径和强度,进而调制中国东部降水时空演变。在青藏高原热源强和弱年,中国降水变率空间分布特征分别为“北涝南旱”和“南涝北旱”。青藏高原视热源强(弱)异常变化“强信号”将对东亚与南亚区域的季风水汽输送结构,以及夏季风降水时空分布的变异具有“前兆性”的指示意义。(3)长江中下游地区作为独特南北两支水汽流的汇合带,该地区夏季青藏高原热源与水汽通量相关矢特征呈类似于青藏高原多雪与少雪年水汽通量偏差场中水汽汇合区显著特征差异,揭示了冬季青藏高原积雪冷源影响中国东部夏季长江流域梅雨水汽输送结构特征。(4)中国降水的年代际变化基本型态为中国东部呈“南涝北旱趋势”,西北区域呈现出“西部转湿趋势”。但基于近10年青藏高原春季视热源出现“降后回升”趋势,中国东部“南涝北旱”的降水格局已出现转折趋势。 相似文献
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青藏高原冬季积雪异常对东,南亚夏季风影响的初步数值模拟研究 总被引:10,自引:2,他引:10
利用一个耦合了简化的简单生物圈模式的大气环流谱模式(SSiB-GCM),初步探讨了青藏高原冬季积雪异常对东、南亚夏季季风环流和降水的影响及其机理。结果表明,高原地区积雪增加将使随后地夏季东、南来季风明显减弱,主要表现为东、南亚季风区降水减少,索马里急流、印度季风的印度西南气流弱弱。另外,还提出欧亚大陆雪盖与整个高原雪盖和高原东部雪盖对东、南亚夏季风影响的敏感问题。与欧亚大陆雪盖相比,高原雪盖是影响 相似文献
9.
本文利用国家气象中心提供的逐日地面积雪深度和积雪日数数据,以及NOAA的大气环流再分析资料,通过合成分析等方法,对1961—2013年青藏高原冬春季积雪高原整体、高原东部、高原西部进行了年际和年代际趋势分析,结果表明,青藏高原整体冬、春季积雪的变化趋势一致,雪深呈现"少雪—多雪—少雪—多雪"的变化趋势,积雪日数呈现"少雪—多雪—少雪"的变化趋势。高原东(西)部积雪在20世纪60—70年代均明显增加,20世纪80—90年代均减少,20世纪90年代末东部春季和冬季积雪减少更为显著,而西部地区除了春季积雪日数变化不大,春、冬季积雪雪深和冬季积雪日数均明显增加。其次,对青藏高原东、西部地区多(少)雪年的划分,发现高原东部和西部地区积雪异常年对应的大气环流形势也存在差异。最后,进一步分析了青藏高原不同区域积雪异常年环流形势变化特征及其对我国夏季降水的影响,发现高原东(西)部积雪异常年时我国夏季降水分布存在显著差异,因此,在将高原积雪作为气候预测因子的时候,应当考虑东部和西部积雪异常不同所产生影响的差异。 相似文献
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《高原气象》2020,(1)
为了得到适用于青藏高原积雪研究的高分辨率、长时间序列的区域尺度资料,利用近30年逐月区域气候系统模式BCC?CSM(m)模拟的1. 125°×1. 125°积雪深度资料、卫星遥感反演的0. 25°×0. 25°积雪深度资料、ERA?Interim 0. 75°×0. 75°地面感热再分析资料和中国气象数据网提供的0. 5°×0. 5°降水资料,评估了BCC?CSM(m)模式对高原积雪深度时空演变的模拟性能及其对高原感热和我国夏季降水的影响,为夏季降水预测提供参考依据。结果表明,BCC?CSM(m)模式能够较好再现冬季高原积雪的时空变化特征,在缺少有效实测积雪资料的高原地区不失为一种分辨率高、时间序列长的代用资料。冬季高原积雪和春季地表感热之间存在反相变化,而且两者的空间分布型存在显著的负相关关系。冬季高原积雪与我国夏季降水存在一定的相关关系,即:与长江中下游地区、四川地区、新疆北部地区、东北东部和高原南部夏季降水呈显著正相关关系,而与华南和东北北部地区呈显著负相关关系。冬季高原积雪存在全区多雪型、全区少雪型、东南少西北多型和东南多西北少型4种空间分布模态,而且不同高原积雪模态对我国夏季降水的影响不同。 相似文献
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Decadal Relationship Between Atmospheric Heat Source and Winter-Spring Snow Cover over the Tibetan Plateau and Rainfall in East China 
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下载免费PDF全文 By using a reverse computation method and the NCEP/NCAR daily reanalysis data from 1960 to 2004, the atmospheric heat source (AHS) was calculated and analyzed. The results show that AHS over the Tibetan Plateau (TP) and its neighboring areas takes on a persistent downtrend in spring and summer during the foregone 50 years, especially the latest 20 years. Snow depth at 50 stations over the TP in winter and spring presents an increase, especially the spring snow depth exhibits a sharp increase in the late 1970s. A close negative correlation exists between snow cover and AHS over the TP and its neighboring areas, as revealed by an SVD analysis, namely if there is more snow over the TP in winter and spring, then the weaker AHS would appear over the TP in spring and summer. The SVD analysis between AHS over the TP in spring and summer and rainfall at 160 stations indicates that the former has a negative correlation with summer precipitation in the middle and lower reaches of the Yangtze River, and a positive correlation with that in South China and North China. The SVD analysis of both snow cover over the TP in winter and spring and rainfall at the same 160 stations indicates that the former has a marked positive correlation with precipitation in the middle and lower reaches of the Yangtze River, and a reversed correlation in South China and North China. On the decadal scale, the AHS and winter and spring snow cover over the TP have a close correlation with the decadal precipitation pattern shift (southern flood and northern drought) in East China. The mechanism on how the AHS over the TP influences rainfall in East China is discussed. The weakening of AHS over the TP in spring and summer reduces the thermodynamic difference between ocean and continent, leading to a weaker East Asian summer monsoon, which brings more water vapor to the Yangtze River Valley and less water vapor to North China. Meanwhile, the weakening of AHS over the TP renders the position of the subtropical high further westward and the r 相似文献
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青藏高原南、北积雪异常与中国东部夏季降水关系的数值试验研究 总被引:6,自引:2,他引:4
青藏高原冬、春积雪有着显著的南、北空间差异,本文利用通用地球系统模式(CESM)设计了增加高原南、北冬、春积雪的敏感性试验,结果表明:当高原南部冬、春积雪异常偏多,长江及其以北地区夏季降水偏多,华南大部分地区夏季降水偏少;而当高原北部冬、春积雪异常偏多,华北及东北地区夏季降水偏多,长江下游南部地区夏季降水偏少,雨带更偏北。青藏高原南、北部冬、春积雪异常影响中国东部夏季降水的物理机制的分析结果表明,高原不同区域(南部和北部)冬、春积雪异常引起的非绝热加热异常效应都可持续到夏季,且北部积雪异常持续时间更长。高原南部和北部积雪异常偏多均会减弱高原北侧上空大气的水平温度梯度,进而减弱高原北侧西风急流的位置及强度,进而影响下游出口区处急流的强度和位置,且高原北部积雪异常偏多的影响更大。当高原南部积雪异常偏多,急流出口区的西风急流加强且偏南;而高原北部积雪异常偏多,出口区的西风急流减弱且偏北。相应地,对流层中层500 hPa西太平洋副热带高压减弱,低层850 hPa异常反气旋环流,影响中国东部地区水汽输送,从而影响了中国东部地区夏季雨带的变化。当高原南部积雪异常偏多,异常反气旋性环流位于东海附近,有利于更多水汽输送至长江流域,华南水汽输送减少;当高原北部积雪异常偏多,异常反气旋性环流相对偏北,更有利于华北及东北水汽输送,雨带偏北。 相似文献
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Assessing the Impacts of Initial Snow Conditions over the Tibetan Plateau on China Precipitation Prediction Using a Global Climate Model 下载免费PDF全文
下载免费PDF全文 CHEN Hong 《大气和海洋科学快报》2014,(2):81-86
Two ensemble experiments were conducted using a general atmospheric circulation model. These experiments were used to investigate the impacts of initial snow anomalies over the Tibetan Plateau(TP) on China precipitation prediction. In one of the experiments, the initial snow conditions over the TP were climatological values; while in the other experiment, the initial snow anomalies were snow depth estimates derived from the passive microwave remote-sensing data. In the current study, the difference between these two experiments was assessed to evaluate the impact of initial snow anomalies over the TP on simulated precipitation. The results indicated that the model simulation for precipitation over eastern China had certain improvements while applying a more realistic initial snow anomaly, especially for spring precipitation over Northeast China and North China and for summer precipitation over North China and Southeast China. The results suggest that seasonal prediction could be enhanced by using more realistic initial snow conditions over TP, and microwave remote-sensing snow data could be used to initialize climate models and improve the simulation of eastern China precipitation during spring and summer. Further analyses showed that higher snow anomalies over TP cooled the surface, resulting in lower near- surface air temperature over the TP in spring and summer. The surface cooling over TP weakened the Asian summer monsoon and brought more precipitation in South China in spring and more precipitation to Southeast China during summer. 相似文献
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春夏季青藏高原积雪对中国夏末秋初
降水的影响及其可能机制 总被引:5,自引:1,他引:4
本文首先利用最大协方差分析方法,探讨青藏高原积雪与中国降水之间的联系,发现中国夏末秋初(8~10月,简称ASO)降水与前期及同期高原积雪有着显著联系,当春夏季青藏高原西部多雪时,其后ASO中国长江及其以南地区多雨,而东部沿海的狭长区域少雨。进一步引入最大响应估计等方法,研究中国区域降水对高原积雪异常的响应及其可能的物理机制,结果表明,冬春季高原多雪异常可持续到夏季,并通过改变地表热力状况,导致ASO南亚高压减弱,同时在高、低空激发出两支波列:高层200 hPa波列沿中高纬西风急流传播,自高原经蒙古到达日本呈现明显的“负—正—负”位势高度异常传播,日本上空为气旋性异常环流;低层850 hPa波列起于高原,经孟加拉湾至中国南海,沿着西南气流传播,导致台湾附近的反气旋性异常环流,其西侧的偏南气流,将南海丰富的水汽输送至中国南部湖南、广西;而高层中心位于日本的气旋性异常环流西侧的偏北气流利于北方天气尺度扰动向南移动,它们为长江中下游及其以南地区多雨提供了有利条件。进一步计算定常波波数也表明,高层西风急流与低层西南季风气流作为波导,有利于高原上空的扰动沿着高、低空2支通道向东传播。由于东部沿海浙江、福建为正位势高度异常区,低层反气旋性异常环流则抑制了该区域的降水。 相似文献
15.
利用耦合的全球海气模式(NCAR CCSM3), 对青藏高原春季土壤湿度异常影响我国夏季7月降水的机制进行了数值模拟。结果表明, 高原6~62 cm深度的中层土壤湿度异常与表层土壤湿度异常有很好的一致性, 相对而言, 中层土壤湿度异常的持续性较好。若5月高原中层土壤偏湿, 则春末至夏初高原地面蒸发、 潜热通量增加, 而感热通量、 地面温度降低, 高原表面的加热作用减弱, 使得印度高压西撤偏晚, 环流系统的季节性转换偏晚, 东亚地区形成有利于我国夏季出现第I类雨型的环流分布形势, 使我国东部雨带偏北, 华北地区多雨, 江淮地区降水偏少, 华南地区降水偏多; 反之亦然。 相似文献
16.
Interannual Variability of Snow Depth over the Tibetan Plateau and Its Associated Atmospheric Circulation Anomalies 下载免费PDF全文
下载免费PDF全文 MAO Jiang-Yu 《大气和海洋科学快报》2010,3(4):213-218
The interannual variability of wintertime snow depth over the Tibetan Plateau(TP) and related atmospheric circulation anomalies were investigated based on observed snow depth measurements and NCEP/NCAR reanalysis data.Empirical orthogonal function(EOF) analysis was applied to identify the spatio-temporal variability of wintertime TP snow depth.Snow depth anomalies were dominated by a monopole pattern over the TP and a dipole structure with opposite anomalies over the southeastern and northwestern TP.The atmospheric circulation conditions responsible for the interannual variability of TP snow depth were examined via regression analyses against the principal component of the most dominant EOF mode.In the upper troposphere,negative zonal wind anomalies over the TP with extensively positive anomalies to the south indicated that the southwestward shift of the westerly jet may favor the development of surface cyclones over the TP.An anomalous cyclone centered over the southeastern TP was associated with the anomalous westerly jet,which is conducive to heavier snowfall and results in positive snow depth anomalies.An anomalous cyclone was observed at 500 hPa over the TP,with an anomalous anticyclone immediately to the north,suggesting that the TP is frequently affected by surface cyclones.Regression analyses revealed that significant negative thickness anomalies exist around the TP from March to May,with a meridional dipole anomaly in March.The persistent negative anomalies due to more winter TP snow are not conducive to earlier reversal of the meridional temperature gradient,leading to a possible delay in the onset of the Asian summer monsoon. 相似文献
17.
The evident effects of the thermal anomalies over the Tibetan Plateau (TP) and its vicinities are summarized and discussed in this paper. By the singular value decomposition (SVD) technique and numerical simulations of the effect of the snow depth anomaly over the TP, it is shown that the snow depth anomaly, especially in winter, is one of the factors influencing precipitation in China, and the winter snow anomaly is more important than the spring one. The relations between the sensible heat anomaly over the TP and the intensity of the South China Sea summer monsoon (SCSSM) are studied, too, and two key areas of the sensible heat anomaly over the TP are found. The relationships between the South Asia High (SAH). and the precipitation in the years with typical droughts or floods in the mid to lower valleys of the Yangtze River (MLVYR) and North China are investigated in some detail. It is found that not only the intensity of the SAH over the TP, but also the 100-hPa height in a large area influences the precipitation in the above two regions. The effects of the SAH on the onsets of the tropical Asian summer monsoon (TASM) including the SCSSM and the tropical Indian summer monsoon (TISM) are studied as well. It is found that the onset times of both the SCSSM and the TISM are highly dependent upon the latitudinal position of the SAH center. 相似文献
18.
Persistence of Snow Cover Anomalies over the Tibetan Plateau and the Implications for Forecasting Summer Precipitation over the Meiyu-Baiu Region 下载免费PDF全文
下载免费PDF全文 The present reported study investigated the persistence of snow anomalies over the Tibetan Plateau(TP) from the preceding seasons to summer and the relationship between the previous snow cover anomaly and summer precipitation over East Asia. The results showed that, relative to other snow indices, such as the station observational snow depth(SOSD) index and the snow water equivalent(SWE) index, the snow cover area proportion(SCAP) index calculated from the SWE and the percentage of visible snow of the Equal-Area Scalable Earth Grids(EASE-grids) dataset has a higher persistence in interannual anomalies, particularly from May to summer. As such, the May SCAP index is significantly related to summer precipitation over the Meiyu-Baiu region. The persistence of the SCAP index can partly explain the season-delayed effect of snow cover over the TP on summer rainfall over the Meiyu-Baiu region besides the contribution of the soil moisture bridge. The preceding SST anomaly in the tropical Indian Ocean and ENSO can persist through the summer and affect the summer precipitation over the Meiyu-Baiu region. However, the May SCAP index is mostly independent of the simultaneous SSTs in the tropical Indian Ocean and the preceding ENSO and may affect the summer precipitation over the Meiyu-Baiu region independent of the effects of the SST anomalies. Therefore, the May SCAP over the TP could be regarded as an important supplementary factor in the forecasting of summer precipitation over the Meiyu-Baiu region. 相似文献