亚洲—太平洋季风区的遥相关研究   总被引：15，自引：6，他引：9  

丁一汇  刘芸芸 《气象学报》2008,66(5):670-682

亚洲-太平洋季风区各季风子系统间的相互作用对季风区甚至全球的气候变化都有非常显著的影响.文中根据国内外相关研究,重点分析和评述了在亚洲-太平洋季风区中4种季节内时间尺度的遥相关关系,清楚地揭示了印度夏季风、东亚夏季风和西北太平洋夏季风之间的相互作用.研究发现:(1) 在亚洲季风爆发初期,印度夏季风的爆发相对于中国长江流域梅雨的开始存在相差大约两周的超前关系,形成从印度西南部经孟加拉湾到达中国长江流域及日本南部的遥相关型,即"南支"遥相关型.(2) 在季风盛行期间,长江流域降水明显受热带西北太平洋夏季风的影响,与西北太平洋夏季风降水呈反相关关系,即当季风减弱时,长江流域夏季降水偏多.(3) 与长江流域降水相反,华北雨季(7月第4候-8月第3候)则与西北太平洋夏季风降水呈正相关关系,当西北太平洋夏季风强时,西太平洋副热带高压异常偏北偏东,副高西南侧的异常东南水汽输送在中国华北地区上空辐合,给该地区降水偏多提供了充足的水汽条件.(4) 华北夏季降水同时还与印度夏季风呈正相关关系,在夏季风盛行期间,形成由印度西北部经青藏高原到中国华北地区的西南-东北走向的遥相关型,即"北支"遥相关型. 上述4种遥相关关系,反映了亚洲夏季风季节北推过程中,印度夏季风、东亚夏季风和西北太平洋夏季风子系统之间的关联.  相似文献   

卫星遥感结合地面观测资料对中国西北干旱区地表热力输送系数的估算   总被引：3，自引：0，他引：3  

王慧  李栋梁 《大气科学》2010,34(5):1026-1034

本文利用黑河野外试验 (HEIFE) 地面观测资料, 采用空气动力学方法计算了干旱区内不同下垫面的地表热力输送系数CH, 结合由美国国家海洋和大气局 (NOAA) 系列卫星遥感观测的反映地表植被特征的归一化差值植被指数 (NDVI) 资料, 经拟合得到了针对我国西北干旱区不同下垫面的CH-NDVI参数化关系式, 并对此关系式进行了合理性检验。结果表明: 对于区域尺度而言, 在缺乏用其他方法获得较准确的区域CH值的情况下, 利用卫星遥感结合地面观测资料对其估算是较为可靠的方法。  相似文献   

我国东、西部夏季水汽输送特征及其差异   总被引：11，自引：6，他引：5  

黄荣辉  陈际龙 《大气科学》2010,34(6):1035-1045

本文利用ERA-40再分析每日资料分析了我国东部季风区与西北干旱—半干旱区夏季1971～2000年气候平均的水汽输送特征及其差异, 分析结果表明我国东部季风区与西北干旱—半干旱区夏季气候平均的水汽输送特征有明显的差异。由于亚洲夏季风从孟加拉湾、 南海和热带西太平洋输送大量水汽到我国东部季风区, 故在东部季风区夏季经向水汽输送通量比纬向水汽输送通量大。而西北干旱—半干旱区受中纬度西风带的影响, 夏季纬向水汽输送通量比经向水汽输送通量大, 且此区域夏季无论纬向或者经向水汽输送通量均比东部季风区的水汽输送通量小一量级。并且, 分析结果还表明: 我国东部季风区由于湿度大, 故夏季水汽输送通量的散度不仅依赖于湿度平流, 而且依赖于风场的辐合、 辐散, 而西北干旱—半干旱区夏季水汽输送通量的散度主要依赖于湿度平流。此外, 分析结果还表明了我国东部季风区的水分平衡与西北干旱—半干旱区的水分平衡也有明显的不同。  相似文献   

环渤海地区1961—2007年极端强降水时空变化特征   总被引：2，自引：0，他引：2  

郭军  李明财  段丽瑶 《气候变化研究进展》2010,6(5):319-324

20世纪90年代以来,环渤海地区降水总量持续偏少,极端强降水和干旱缺水问题十分突出。利用环渤海地区60个台站1961—2007年逐日降水资料,应用百分位方法确定极端强降水阈值,分析了极端强降水量、降水强度和频率的空间分布及时间变化趋势。结果表明:环渤海地区极端降水强度大、频率高的地区与年降水量高值区相一致,说明极端降水量的多少影响年降水量;极端降水日数呈减少趋势,特别是京津冀中部地区减少显著;极端降水多发生在7月中旬到8月中旬,最高频次在7月下旬,近10年极端降水季节分配比较分散,很少出现每候25站次以上的极端强降水;间隔30d以上的极端强降水近年来增加明显。  相似文献   

Variations of Terrestrial Water Storage in the Yangtze River Basin under Climate Change Scenarios          下载免费PDF全文

MA Qian  XIE Zheng-Hui  ZHAO Lin-Na 《大气和海洋科学快报》2010,3(6):293-298

In this study, the water balance-based Precipitation-Evapotranspiration-Runoff (PER) method combined with the land surface model Variable Infiltration Capacity (VIC) was used to estimate the spatiotemporal variations of terrestrial water storage (TWS) for two periods, 1982–2005 (baseline) and 2071–2100, under future climate scenarios A2 and B2 in the Yangtze River basin. The results show that the estimated TWS during the baseline period and under the two future climate scenarios have similar seasonal amplitudes of 60–70 mm. The higher values of TWS appear in June during the baseline period and under the B2 scenario, whereas the TWS under A2 shows two peaks in response to the related precipitation pattern. It also shows that the TWS is recharged from February to June during the baseline period, but it is replenished from March to June under the A2 and B2 scenarios. An analysis of the standard derivation of seasonal and interannual TWS time series under the three scenarios demonstrates that the seasonal TWS of the southeastern part of the Yangtze River basin varies remarkably and that the southeastern and central parts of the basin have higher variations in interannual TWS. With respect to the first mode of the Empirical Orthogonal Function (EOF), the inverse-phase change in seasonal TWS mainly appears across the Guizhou-Sichuan-Shaanxi belt, and the entire basin generally represents a synchronous change in interannual TWS. As a whole, the TWS under A2 presents a larger seasonal variation whereas that under B2 displays a greater interannual variation. These results imply that climate change could trigger severe disasters in the southeastern and central parts of the basin.  相似文献   

An overview of dry-wet climate variability among monsoon-westerly regions and the monsoon northernmost marginal active zone in China   总被引：7，自引：2，他引：5  

钱维宏  丁婷  胡豪然  林祥  秦爱民 《大气科学进展》2009,26(4):630-641

Climate in mainland China can be divided into the monsoon region in the southeast and the westerly region in the northwest as well as the intercross zone, i.e., the monsoon northernmost marginal active zone that is oriented from Southwest China to the upper Yellow River, North China, and Northeast China. In the three regions, dry-wet climate changes are directly linked to the interaction of the southerly monsoon flow on the east side of the Tibetan Plateau and the westerly flow on the north side of the Plateau from the inter-annual to inter-decadal timescales. Some basic features of climate variability in the three regions for the last half century and the historical hundreds of years are reviewed in this paper. In the last half century, an increasing trend of summer precipitation associated with the enhancing westerly flow is found in the westerly region from Xinjiang to northern parts of North China and Northeast China. On the other hand, an increasing trend of summer precipitation along the Yangtze River and a decreasing trend of summer precipitation along the monsoon northernmost marginal active zone are associated with the weakening monsoon flow in East Asia. Historical documents are widely distributed in the monsoon region for hundreds of years and natural climate proxies are constructed in the non-monsoon region, while two types of climate proxies can be commonly found over the monsoon northernmost marginal active zone. In the monsoon region, dry-wet variation centers are altered among North China, the lower Yangtze River, and South China from one century to another. Dry or wet anomalies are firstly observed along the monsoon northernmost marginal active zone and shifted southward or southeastward to the Yangtze River valley and South China in about a 70-year timescale. Severe drought events are experienced along the monsoon northernmost marginal active zone during the last 5 centuries. Inter-decadal dry-wet variations are depicted by natural proxies for the last 4--5 centuries in several areas over the non-monsoon region. Some questions, such as the impact of global warming on dry-wet regime changes in China, complex interactions between the monsoon and westerly flows in Northeast China, and the integrated multi-proxy analysis throughout all of China, are proposed.  相似文献   

The Relationship of Land-Ocean Thermal Anomaly Difference with Mei-yu and South China Sea Summer Monsoon     

WANG Zhifu  QIAN Yongfu 《大气科学进展》2009,26(1):169-179

Based on the NCEP/NCAR reanalysis data for the period of 1948--2004 and the monthly rainfall data at 160 stations in China from 1951 to 2004, the relationships among the land-ocean temperature anomaly difference in the mid-lower troposphere in spring (April--May), the mei-yu rainfall in the Yangtze River-Huaihe River basin, and the activities of the South China Sea summer monsoon (SCSSM) are analyzed by using correlation and composite analyses. Results show that a significant positive correlation exists between mei-yu rainfall and air temperature in the middle latitudes above the western Pacific, while a significant negative correlation is located to the southwest of the Baikal Lake. When the land-ocean thermal anomaly difference is stronger in spring, the western Pacific subtropical high (WPSH) will be weaker and retreat eastward in summer (June--July), and the SCSSM will be stronger and advance further north, resulting in deficient moisture along the mei-yu front and below-normal precipitation in the mid and lower reaches of the Yangtze River, and vice versa for the weaker difference case. The effects and relative importance of the land and ocean anomalous heating on monsoon variability is also compared. It is found that the land and ocean thermal anomalies are both closely related to the summer circulation and mei-yu rainfall and SCSSM intensity, whereas the land heating anomaly is more important than ocean heating in changing the land-ocean thermal contrast and hence the summer monsoon intensity.  相似文献   

重庆2008年7月21日强对流天气成因及其特征   总被引：3，自引：0，他引：3  

牟容  余君  刘德 《气象》2009,35(5):49-54

对2008年7月21日重庆市一次强对流天气过程进行诊断分析,通过分析天气背景,雷达回波,并应用四维变分同化方法反演风场,研究了强对流天气的发展机制.结果表明:高层冷空气入侵和中低层低涡系统强盛的暖湿气流形成的辐合切变是发生强对流的主要原因.雷达观测具有明显的弱回波区和"逆风区";反演水平风场表现为低层强回波前部有一条辐合上升带,到中层辐合上升带与强回波区重合,高层则对应辐散区;从风场的垂直剖面来看,强对流后部为入流区,到达中部后,形成强烈的上升气流,低层辐合带和强烈的上升气流形成强回波.在前部弱回波区处存在强降水下落形成的出流,该气流与暖湿气流辐合造成了浅薄的出流边界.  相似文献   

黄河源区草地退化对局地气候环境影响的数值模拟   总被引：5，自引：3，他引：2       下载免费PDF全文

柳媛普  吕世华  李锁锁  高艳红 《高原气象》2009,28(2):327-334

土地覆盖变化会影响到近地层各气象要素发生不同程度的变化.利用中尺度数值模式MM5,设计了一个控制试验和一个敏感性试验.通过对2003年7月一个月的积分,模拟了黄河源区草原退化对局地气候环境的影响.结果表明,黄河源区草原退化导致该地区2 m高度气温及地表温度明显升高;空气湿度及土壤湿度不同程度减小;草原退化后降水的减小影响到径流减小;草原退化后还引起退化区感热通量增加,潜热通量减小,有效通量(感热通量+潜热通量)减小.与草地农牧化相比,草原退化对气候环境的影响程度更强.  相似文献   

2006年川渝地区夏季干旱的成因分析   总被引：2，自引：1，他引：1  

刘银峰  徐海明  雷正翠 《南京气象学院学报》2009,32(5):686-694

利用NCEP/NCAR再分析月平均资料、全国160站降水资料、向外长波辐射OLR（outgoinglongwave radiation）资料和所计算的热源资料,分析了2006年夏季东亚大气环流的异常特征,并研究了热力异常与川渝地区夏季降水的关系。结果表明,2006年夏季由南向北的水汽输送较常年偏弱;西太洋副热带高压较常年异常偏强,脊线位置明显偏北,川渝地区受高压系统影响盛行下沉气流,中高纬环流场则表现为乌拉尔山地区和东北亚区域无明显阻塞高压形势,冷空气活动比常年弱;南亚高压比常年偏北偏强,持续控制川渝地区;2006年夏季青藏高原热源偏弱,热带西太平洋暖池区热源偏强,是引起西太平洋副热带高压偏北偏强的重要原因之一。川渝地区夏季降水与西太平洋副热带高压的异常变化有密切关系,川渝地区夏季干旱年,西太平洋副热带高压偏北,并且引起西太平洋副热带高压偏北的原因与2006年类似。  相似文献