共查询到19条相似文献,搜索用时 140 毫秒
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目前,仍没有一套公认的能够很好的描述高原土壤湿度变化特征的替代资料,为此利用收集到的多套观测资料作为参考,分别对各种替代资料在高原的适用性进行了评估。结果表明:(1)观测资料表明,高原的土壤湿度在表层、中层、深层的变化具有较好的一致性,表层与中层、中层与深层的土壤湿度相关系数均在0.8以上。(2)卫星反演资料SSM/I RETRIEVALS在各个站点与观测值的相关系数都为正,在高原东南部、中部、北部相关系数都在0.5以上,且标准差与高原东南和中部的观测标准差较为接近,适用于高原的大范围地区,是研究青藏高原土壤湿度多年变化特征的一套较好的替代资料。(3)春季高原土壤湿度的空间分布具有南部边缘较大、由东南向西北递减的特征,大部分地区的土壤湿度具有明显的线性增加趋势;去除趋势后,高原东、西各有一个均方差大值区,东、西关键区内的土壤湿度从春到夏都具有较好的持续性,可以作为预测我国夏季降水的重要因子。 相似文献
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利用气象台站观测地表温度,比较和分析了ERA-Interim、NCEP/NCAR和NCEP/DOE再分析地表温度资料在青藏高原的适用性.结果表明:三种再分析资料都揭示了青藏高原地表温度的基本特征,并较好地描述了高原地表温度的季节变化和年际变化特征;但三种再分析资料都比观测地表温度明显偏低,且对地表温度的长期变化趋势估计不足.比较而言,ERA-1nterim再分析地表温度产品在青藏高原的适用性最好,与观测地表温度的相关最显著,且能较好地反映高原地表温度的异常变化强度,可作为研究高原地表温度年际变化的代用资料;而NCEP/NCAR和NCEP/DOE 再分析地表温度产品在青藏高原的适用性不佳,其适用时段和适用区域需要进一步考察. 相似文献
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土壤湿度是陆面过程的重要参量,可以通过影响土壤本身的热力性质和水文过程,导致局部大气环流的改变以及区域性短期气候异常。青藏高原作为全球气候变化的敏感区,其地气间的水分与能量交换对亚洲季风和全球大气循环有着极大的影响,且高原地区的土壤水分数据能够为陆-气相互作用和数值模拟等研究提供重要的观测信息和初始输入数据。文中综述了青藏高原土壤湿度观测和研究对气候变化影响的重要性,高原土壤湿度观测站网建设现状,各种土壤湿度替代资料的适用性和评估研究,以及高原土壤湿度时空分布特征对降水的影响与气候变化响应,并提出了今后青藏高原土壤湿度研究着重解决的问题。 相似文献
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本文利用1981~2016年的CRUNCEP资料(0.5°×0.5°)作为大气驱动数据,驱动CLM4.5(Community Land Model version 4.5)模式模拟了青藏高原地区1981~2016 年的土壤湿度时空变化。将模拟数据与台站观测资料、再分析资料(ERA-Interim和GLDAS-CLM)和微波遥感FY-3B/MWRI土壤湿度资料对比验证,表明了CLM4.5模拟资料可以合理再现青藏高原地区土壤湿度的空间分布和长期变化趋势。而且基于多种卫星遥感资料建立的较高分辨率(0.1°×0.1°)的青藏高原地表数据更加细致地刻画了土壤湿度的空间变化。对比结果表明:CLM4.5模拟土壤湿度与各个台站观测的时空变化一致,各层土壤湿度的模拟和观测均显著相关,且对浅层的模拟优于深层,但模拟结果比台站观测系统性偏大。模拟与再分析资料和微波遥感资料土壤湿度的空间分布具有一致性,均表现为从青藏高原的西北部向东南部逐渐增加的分布特点,三江源湿地和高原东南部为土壤湿度的高值区,柴达木盆地和新疆塔里木盆地的沙漠地区为低值区,土壤湿度由浅层向深层增加。土壤湿度的长期变化趋势基本表现为“变干—变湿”相间的带状分布,不同层次的土壤湿度变化趋势基本一致。模拟资料也合理地再现了夏季土壤湿度逐月的变化:高原西南地区的土壤湿度明显大范围增加,北部的柴达木盆地的干旱范围也明显的向北收缩,高原南部外围土壤湿度也明显增加,CLM4.5模拟土壤湿度比再分析资料和微波遥感资料更加细致地描述了夏季逐月土壤湿度空间分布及其变化特征。 相似文献
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《高原气象》2017,(1)
利用1979-2014年欧洲中期天气预报中心(ECMWF)的ERA-Interim再分析资料,构建了一个能更有效反映季风演变过程的高原季风新指数(ZPMI),并与已有高原季风指数TPMI、DPMI和QPMI进行对比分析。发现TPMI反映的高原夏季风爆发和撤退的时间较ZPMI、DPMI提前1~2个月左右,ZPM I能更好的反映高原上季风降水的年变化和年际变化特征。而其冬季风和夏季风具有相似的年际、年代际变化特征,总体均呈现上升的趋势,且夏季风增强的趋势更显著。同时,ZPMI也能够较好的描述高原上的气象要素特征,即:在强季风年,高原中、东(西)部降水多(少),气温高(低);而弱季风年,则与之相反。高原晚春(4-5月)土壤湿度与当年高原夏季风存在显著的相关,当4-5月高原中部、东部地区土壤湿度偏大(小)、西部土壤湿度偏小(大)时,高原夏季风偏强(弱)。 相似文献
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夏季青藏高原不同层次土壤湿度时空变化特征 总被引:1,自引:0,他引:1
基于1950—2009年GLDAS Noah 2.0逐月平均土壤湿度资料,分析了夏季青藏高原各层土壤湿度的时空变化特征。结果表明:(1)夏季青藏高原各层土壤湿度整体上呈自南向北递减的空间分布,但在高原中部地区中层、深层土壤湿度均有一个极值中心。(2)夏季高原中东部地区表层、浅层、中层、深层土壤湿度之间的差值(深层与中层除外)均表现为"上湿下干"的垂直分布,而中部偏西地区各层土壤湿度差值则表现为"下湿上干"的垂直分布。(3)夏季高原各层土壤湿度第一模态均呈现西南—东北反向型分布,且随着深度的增加,零线向东北移。(4)夏季高原主体各层土壤湿度的年际变化特征明显,除深层(呈现不显著增加趋势)外整体均呈现显著下降趋势,前期土壤湿度较高,后期较低。从空间趋势分布来看,除深层土壤湿度在高原中部有增大趋势外,各层土壤湿度变化趋势在高原上均以减小为主。(5)去趋势后,除深层外其他各层土壤湿度最大年际变化幅度在高原中部随着土层的增加而减小,而高原中东部则随土层的增加而增大。 相似文献
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多种土壤湿度资料在中国地区的对比分析 总被引:1,自引:0,他引:1
利用1992—2012年中国区域土壤湿度观测资料对目前使用较为广泛的5套土壤湿度资料(ERA-Interim、NCEP再分析资料、GLDAS同化资料、CPC模式资料和AMSR-E卫星反演资料)的适用性进行检验,分析5套资料对中国区域土壤湿度的时空分布特征和变化趋势的描述能力。结果表明:5套资料都能大体反映暖季中国区域土壤湿度东南湿、西北干,自东南向西北递减的分布格局以及西北干旱区和半干旱区变湿、长江流域部分地方变干的变化趋势,其中CPC资料最接近观测事实,并能较好地表现局地特征;在描述土壤湿度的季节变化和年际变化方面,GLDAS和NCEP资料与观测数据的相关性较好,能较好反映土壤湿度的时间演变特征。进一步利用检验效果较好的GLDAS、NCEP和CPC资料分别对中国区域土壤湿度时间和空间的长期变化趋势分析发现:中国区域标准化年平均土壤湿度在1948—1996年处在相对湿润期,而1996—2012年处在相对干旱期;中国区域年平均土壤湿度的空间变化特征是东部变干、西部变湿,自东北、华北至西南呈现一个干旱化带。 相似文献
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基于NCAR大气模式CAM3.1模式,设计了有、无土壤湿度年际异常两组试验对中国区域近40a(1961-2000年)气候进行了模拟。从气候态和年际变率的角度,通过分析两组试验的差值场来探讨土壤湿度年际异常对气候模拟的影响,并初步探讨了影响的可能机制。结果表明:模式模拟的温度和降水对土壤湿度的年际异常非常敏感,土壤湿度的年际变化对中国春夏季气候及其年际变率均有显著影响。当不考虑土壤湿度年际异常时,模式模拟的春夏季平均温度、最高温度、最低温度在我国大范围内降低,春夏季降水在东部大部分地区明显减少,西部增加。而模式模拟的春夏季温度、降水年际变率在中国大部分地区减弱。但当考虑土壤湿度的年际变化,则能在一定程度上提高模式对气候年际变率的模拟能力。在进一步分析表明土壤湿度年际异常时,主要通过改变地表能量通量和环流场,对温度、降水产生影响。当不考虑土壤湿度年际异常时,地表净辐射通量减少,地表温度降低,感热通量减少。感热通量差值场的空间变化和温度差值场的空间变化一致,感热通量对温度有一定影响。而潜热通量差值场的空间变化和降水的差值场的空间变化一致,可见降水受地表潜热通量的影响。土壤湿度年际异常引起的环流场的变化也是导致气候变化的原因之一,地表能量和环流场年际变率的改变对春夏季气候年际变率存在一定影响。 相似文献
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土壤湿度对东亚夏季气候潜在可预报性影响的数值模拟 总被引:5,自引:0,他引:5
利用全球大气环流模式NCARCAM3进行了在给定的观测海温条件下的22a(1979—2000年)5—8月的2组集合试验。运用方差分析方法,分析了在气候态和年际变化的表层土壤湿度情况下,CAM3模式模拟的东亚夏季气候潜在可预报性及其差异。结果表明:在给定的观测海温条件下,采用气候态的土壤湿度时,CAM3模式模拟的东亚夏季气候的潜在可预报性偏低;而采用年际变化的土壤湿度时,模拟的夏季气候潜在可预报性有所提高,尤其是在中国西北地区;后者模拟的中国西北地区夏季降水和气温的潜在可预报性比前者的模拟结果提高0.1以上。其原因可能是:采用年际变化的土壤湿度时,模式可以更好地模拟出中国西北地区的地表蒸发量和湍流热通量的年际变化,进而使得模式对该地区夏季气候的预报技巧得到提高。 相似文献
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Recent Progress in the Impact of the Tibetan Plateau on Climate in China 总被引:14,自引:0,他引:14
Studies of the impacts of the Tibetan Plateau (TP) on climate in China in the last four years are reviewed. It is reported that temperature and precipitation over the TP have increased during recent decades. From satellite data analysis, it is demonstrated that most of the precipitation over the TP is from deep convection clouds. Moreover, the huge TP mechanical forcing and extraordinary elevated thermal forcing impose remarkable impacts upon local circulation and global climate. In winter and spring, stream flow is deflected by a large obstacle and appears as an asymmetric dipole, making East Asia much colder than mid Asia in winter and forming persistent rainfall in late winter and early spring over South China. In late spring, TP heating contributes to the establishment and intensification of the South Asian high and the abrupt seasonal transition of the surrounding circulations. In summer, TP heating in conjunction with the TP air pump cause the deviating stream field to resemble a cyclonic spiral, converging towards and rising over the TP. Therefore, the prominent Asian monsoon climate over East Asia and the dry climate over mid Asia in summer are forced by both TP local forcing and Eurasian continental forcing.
Due to the longer memory of snow and soil moisture, the TP thermal status both in summer and in late winter and spring can influence the variation of Eastern Asian summer rainfall. A combined index using both snow cover over the TP and the ENSO index in winter shows a better seasonal forecast.
On the other hand, strong sensible heating over the Tibetan Plateau in spring contributes significantly to anchor the earliest Asian monsoon being over the eastern Bay of Bengal (BOB) and the western Indochina peninsula. Qualitative prediction of the BOB monsoon onset was attempted by using the sign of meridional temperature gradient in March in the upper troposphere, or at 400 hPa over the TP. It is also demonstrated by a numerical experiment and theoretical study that the heating over the TP lea 相似文献
Due to the longer memory of snow and soil moisture, the TP thermal status both in summer and in late winter and spring can influence the variation of Eastern Asian summer rainfall. A combined index using both snow cover over the TP and the ENSO index in winter shows a better seasonal forecast.
On the other hand, strong sensible heating over the Tibetan Plateau in spring contributes significantly to anchor the earliest Asian monsoon being over the eastern Bay of Bengal (BOB) and the western Indochina peninsula. Qualitative prediction of the BOB monsoon onset was attempted by using the sign of meridional temperature gradient in March in the upper troposphere, or at 400 hPa over the TP. It is also demonstrated by a numerical experiment and theoretical study that the heating over the TP lea 相似文献
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Performance of Regional Integrated Environment Modeling System (RIEMS) in precipitation simulations over East Asia 总被引:1,自引:0,他引:1
Deming Zhao 《Climate Dynamics》2013,40(7-8):1767-1787
Regional climate models (RCMs) can provide much more precise information on surface characteristics and mesoscale circulation than general circulation models. This potential for obtaining more detailed model results has motivated to a significant focus on RCMs development in East Asia. The Regional Integrated Environment Modeling System, version 2.0 (RIEMS2.0) has been developed from an earlier RCM, RIEMS1.0, at the Key Laboratory of Regional Climate-Environment for East Asia and Nanjing University. To test the ability of RIEMS2.0 to simulate long-term climate and climate changes in East Asia and to provide a basis for further development and applications, we compare simulated precipitation from 1979 to 2008 (simulation duration from 1 January 1978 to 31 December 2008) to observed meteorological data. The results show that RIEMS2.0 reproduces the spatial distribution of precipitation in East Asia but that the simulation overestimates precipitation. The simulated 30-year precipitation average is 26 % greater than the observed precipitation. Simulated upper and root soil water correlate well with remote sensing derived soil moisture. Annual and interannual variation in the average precipitation and their anomalies are both well reproduced by the model. A further analysis of three subregions representing different latitude ranges shows that there is good correlation and consistency between the simulated results and the observed data. Annual variation, interannual variation of average precipitation, and the anomalies in the three sub-regions are also well captured by the model. The model’s performance on atmospheric circulation and moisture transport simulations is discussed to explore the bias between the simulation and observations. In summary, RIEMS2.0 shows stability and does well in both simulating long-term climate and climate changes in East Asia and in describing subregional characteristics. 相似文献
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MAIN HEATING MODES OVER THE TIBETAN PLATEAU IN JULY AND THE CORRELATION PATTERNS OF CIRCULATION AND PRECIPITATION OVER EAST ASIA* 
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下载免费PDF全文 Based on the 1958-1999 monthly averaged NCEP/NCAR reanalysis data,the REOF analysis is applied to obtain the main spatial modes of normalized atmospheric heating source over the Tibetan Plateau(TP) in July.Results show that the four leading modes are located over the northeast TP,southwest TP.Kashmir and southeast TP respectively,and the cumulative variances are no more than one third of the total.It indicates that the heating source distribution is very complicated over the TP in July.In other words.it is difficult to depict the heating spatial distribution with a few modes.By using wavelet analysis,a 2-4-year variation period is identified in these modes.Moreover,correlation coefficients between each RPC and zonal wind U, meridional wind V.zonal moisture flux Qv,meridional moisture flux Qv,and precipitation rate over East Asia are calculated to construct correlation fields,Results show that different heating modes over the TP correspond to different circulation,moisture flux as well as precipitation patterns,Precipitation over North China(or Kashmir) is negatively(or positively) correlated with REOF1.Similarly.notable negative(or positive) correlation can be found between the rainfall over south part of Southwest China.South China,and the Philippines(or Japan) and the REOF3. Due to high localization of diabatic heating over the TP.it is not enough to study the influence of TP thermal forcing on the climate with an area averaged heating index. 相似文献
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土壤湿度影响中国夏季气候的数值试验 总被引:10,自引:0,他引:10
利用"全球土壤湿度计划第2阶段"提供的土壤湿度资料强迫区域气候模式RegCM3,通过数值试验讨论了土壤湿度对东亚夏季气候模拟效果的影响。结果表明,合理考虑土壤湿度的作用,能够提高区域气候模式对中国夏季降水和2 m气温的空间分布型及逐日变化的模拟效果;模拟结果与观测的相关分析显示,降水和2 m气温的年际变化都得到了有效改进,这种改进在气温上尤为明显。不过上述改进具有区域依赖性。数值试验结果表明,气温对土壤湿度的敏感性强于降水,这也从一个侧面说明提高降水模拟效果的难度。总体而言,合理的土壤湿度能够提高区域气候模式对中国夏季气候的模拟能力。因此,合理描述土壤湿度的变化,是提高中国夏季气候预报技巧的潜在途径之一。 相似文献
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Performance of a regional climate model (RCM), WRF, for downscaling East Asian summer season climate is investigated based on 11-summer integrations associated with different climate conditions with reanalysis data as the lateral boundary conditions. It is found that while the RCM is essentially unable to improve large-scale circulation patterns in the upper troposphere for most years, it is able to simulate better lower-level meridional moisture transport in the East Asian summer monsoon. For precipitation downscaling, the RCM produces more realistic magnitude of the interannual variation in most areas of East Asia than that in the reanalysis. Furthermore, the RCM significantly improves the spatial pattern of summer rainfall over dry inland areas and mountainous areas, such as Mongolia and the Tibetan Plateau. Meanwhile, it reduces the wet bias over southeast China. Over Mongolia, however, the performance of precipitation downscaling strongly depends on the year: the WRF is skillful for normal and wet years, but not for dry years, which suggests that land surface processes play an important role in downscaling ability. Over the dry area of North China, the WRF shows the worst performance. Additional sensitivity experiments testing land effects in downscaling suggest the initial soil moisture condition and representation of land surface processes with different schemes are sources of uncertainty for precipitation downscaling. Correction of initial soil moisture using the climatology dataset from GSWP-2 is a useful approach to robustly reducing wet bias in inland areas as well as to improve spatial distribution of precipitation. Despite the improvement on RCM downscaling, regional analyses reveal that accurate simulation of precipitation over East China, where the precipitation pattern is strongly influenced by the activity of the Meiyu/Baiu rainfall band, is difficult. Since the location of the rainfall band is closely associated with both lower-level meridional moisture transport and upper-level circulation structures, it is necessary to have realistic upper-air circulation patterns in the RCM as well as lower-level moisture transport in order to improve the circulation-associated convective rainfall band in East Asia. 相似文献
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7月青藏高原大气热源空间型及其与东亚大气环流和降水的相关研究 总被引:26,自引:0,他引:26
对1958~1999年的7月份NCEP/NCAR再分析资料中青藏高原区域大气热源强度(整层气柱的总非绝热加热率)做旋转经验正交函数分析,结果表明该区域内大气热源强度的空间分布特征复杂,各地差异显著。前4个REOF型的加热中心位于高原东北部、高原西南部、克什米尔地区以及高原东南部地区上空。小波分析还表明各空间型都有2~4a的变化周期。文中计算了前4个RPC与东亚中、低空纬向风(U)、经向风(V)、纬向水汽通量(Q_u)、经向水汽通量(Q_v)的相关系数,并用这些相关系数构造矢量,进而分析其流场和水汽通量散度场,发现高原不同区域的大气加热异常所对应的东亚大气环流形势及降水也大不相同,由此表明,在研究高原加热对中国气候的影响时,应注意加热的空间分布特征。 相似文献
19.
基于全球降水气候中心(GPCC)和全球降水气候计划(GPCP)的降水数据及ERA-interim再分析资料,分析了1979~2012年冬季青藏高原(简称高原)西侧地区降水的基本特征及影响其年际变率的潜在因子。结果表明高原冬季降水主要发生在其西侧地区且为全区变化一致型,降水所需的水汽主要来自上游地区,从该区域的西边界输入。然而,高原西侧地区冬季降水的年际变率主要由水汽输送的动力过程所决定,表现为高原西侧的西南风异常。此外,高原西侧冬季降水的年际变率与其上游典型的大气内部变率北大西洋涛动和北极涛动相关性不强,而与赤道西印度洋和热带中东太平洋的海温显著相关。热带中东太平洋海温异常通过影响大气环流变化,在印度洋北部激发一个反气旋式的环流异常,使得高原西侧地区出现异常西南风,从而加强了水汽通量输送的动力作用。同时在赤道异常东风的作用下,暖水也向印度洋西部输送堆积。赤道中东太平洋海温的异常可进一步导致西风急流发生南北移动,从而也在一定程度上影响了高原西侧冬季水汽输送以及降水的年际变率。 相似文献