IMPACT OF UPLIFT OF TIBETAN PLATEAU AND CHANGE OF LAND-OCEAN DISTRIBUTION ON CLIMATE OVER ASIA

Using an improved CCM1/NCAR climate dynamic model and a combination distribution ofland-ocean-vegetation during 40-50 MaBP,a series of numerical experiments representingdifferent stages of the Tibetan Plateau uplifting and different land-ocean distributions are designedto discuss the influence of the Plateau uplifting and land-ocean distribution variation on Asianclimate change.It is shown that Tibetan Plateau uplifting can firstly increase the precipitation inChina during the period from initial uplift to half height of modern Tibetan Plateau and thendecrease the rainfall during the time from the half height to the present plateau.At the same time.the uplifting can reduce surface air temperature over China.Besides.the effects of the uplift andland-ocean distribution change on the variation of winter and summer Asian monsoon circulationare also discussed.     

利用CloudSat资料分析青藏高原、高原南坡及南亚季风区云高度的统计特征量

云与辐射的相互作用对全球的天气和气候变化过程有着重要的影响,不同高度的云有着不同的辐射强迫,获得云体高度及其在时空上的变化对研究全球气候的变化有着重要意义。本文利用云卫星上的云廓线雷达(CloudSat/CPR)2006年6月—2007年12月期间的资料,对比分析了青藏高原、高原南坡和南亚季风区域不同云类的云顶、云底高度和云厚统计量。结果表明,在所研究区域单位面积上的云顶和云底高度变化具有一定的时空连续性,不同云类的云顶和云底高度存在不同的变化范围,且随着季节的改变均有明显的变化;同时各区域不同云类的云体厚度在夏季较大,冬季较小;各区域不同云类所占的比例(云量)也具有一定的季节变化规律。     

高原大地形及海洋热力强迫对东亚及北半球环流和气候变化影响的观测研究

本文总结了“青藏高原大地形及西太平洋暖池势力强迫对东亚及全球气候变化的影响”专题五年来的主要研究工作。其中包括青世故高原东部大气热源的时间演变特征,夏半年高原热源异常对我国降水和北半球环流的影响;西沙海温变化特征及其与我南方降水的关系,北太平洋海温主因子特征及其与华南前汛期降水的变化。     

青藏高原热力作用对南海及周边区域夏季气候的影响研究进展

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。      

A COMPARATIVE STUDY OF THE HEATING EFFECTS OF THE TIBETAN PLATEAU AND THE WESTERN PACIFIC*

A zonal domain primitive equation modeling system(ZDMS) is used to study the effects of the initial heating anomalies over the Tibetan Plateau and the western Pacific on the East Asian and the Chinese summer climate,the relative importance and the mechanisms are discussed.Results show that in spite of the different locations of the heating anomalies the influences of the two anomalyareas are much similar to each other when the scaling of the two areas is the same.The two areas of heating anomalies have their own affecting domains in which one is more important than the other.In the western Pacific the heating anomaly over the western Pacific is more evident and in the Tibetan Plateau area the heating anomaly over the Tibetan Plateau is more obvious.For the east part of China the effects of the two heating anomalies both exist and almost have the equal importance.The initial anomaly of the sea surface temperature(SST) over the western Pacific can be kept during the entire time integration while in the Tibetan Plateau it can not be maintained.     

A COMPARATIVE STUDY OF THE HEATING EFFECTS OF THE TIBETAN PLATEAU AND THE WESTERN PACIFIC

A zonal domain primitive equation modeling system(ZDMS)is used to study the effects of theinitial heating anomalies over the Tibetan Plateau and the western Pacific on the East Asian and theChinese summer climate,the relative importance and the mechanisms are discussed.Results showthat in spite of the different locations of the heating anomalies the influences of the two anomalyareas are much similar to each other when the scaling of the two areas is the same.The two areasof heating anomalies have their own affecting domains in which one is more important than the oth-er.In the western Pacific the heating anomaly over the western Pacific is more evident and in theTibetan Plateau area the heating anomaly over the Tibetan Plateau is more obvious.For the eastpart of China the effects of the two heating anomalies both exist and almost have the equal impor-tance.The initial anomaly of the sea surface temperature(SST)over the western Pacific can bekept during the entire time integration while in the Tibetan Plateau it can not be maintained.     

青藏高原地面热源对亚洲季风爆发的热力影响

利用多年NCEP/NCAR再分析全球逐候平均气象场资料和逐旬感热、潜热资料，对亚洲夏季风爆发期间青藏高原及其邻近地区地面加热场的特征进行分析。着重讨论了高原和邻近地区感热加热对亚洲夏季风爆发的影响，具体分析了高原感热加热对亚洲夏季风推进的影响机制，以及对热带低层西风气流的作用。结果发现，中纬度主原的感热加热所造成的经、纬向热力差异是导致亚洲夏季风爆发的原因。亚洲夏季风建立区域和时间的差异与高原感热加热的区域性有关。高原感热加热在南海夏季风爆发前后对南海地区低层西风所流所起的作用不同，在季风爆发前是加速低层西风，在季风爆发后起削弱西风气流的作用。对亚洲夏季风爆发早年和晚年的感热加热进行了对比分析，发现亚洲夏季风爆发时间的年际变化与热源的年际变化有关。     

A Possible Impact of Cooling over the Tibetan Plateau on the Mid-Holocene East Asian Monsoon Climate

By using a 9-level global atmospheric general circulation model developed at the Institute of Atmospheric Physics (IAP9L-AGCM) under the Chinese Academy of Sciences, the authors investigated the response of the East Asian monsoon climate to changes both in orbital forcing and the snow and glaciers over the Tibetan Plateau at the mid-Holocene, about 6000 calendar years before the present (6 kyr BP). With the Earth’s orbital parameters appropriate for the mid-Holocene, the IAP9L-AGCM computed warmer and wetter conditions in boreal summer than for the present day. Under the precondition of continental snow and glacier cover existing over part of the Tibetan Plateau at the mid-Holocene, the authors examined the regional climate response to the Tibetan Plateau cooling. The simulations indicated that climate changes in South Asia and parts of central Asia as well as in East Asia are sensitive to the Tibetan Plateau cooling at the mid-Holocene, showing a significant decrease in precipitation in northern India, northern China and southern Mongolia and an increase in Southeast Asia during boreal summer. The latter seems to correspond to the weakening, southeastward shift of the Asian summer monsoon system resulting from reduced heat contrast between the Eurasian continent and the Pacific and Indian Oceans when a cooling over the Tibetan Plateau was imposed. The simulation results suggest that the snow and glacier environment over the Tibetan Plateau is an important factor for mid-Holocene climate change in the areas highly influenced by the Asian monsoon.     

夏季风爆发前后中国区域对流层顶高度变化特征

利用2008—2014年全国高垂直分辨率的L波段探空资料,统计分析了东亚夏季风爆发前后我国不同区域对流层顶高度变化特征。研究表明:夏季风爆发后,对流层顶高值区向北推进,最大值位于青藏高原南部及其东南部地区;对流层顶高度的向南梯度和向东梯度大值区均由爆发前的30°~40°N北移至40°~50°N;受地面加热和垂直运动的影响,中国东北部和中东部在夏季风爆发后对流层升温,平流层-对流层过渡层降温,大气温度梯度增加,对流层顶上升,其中中国东北部在夏季风爆发前,大气温度廓线为双峰结构,易出现双对流层顶,第一对流层顶较低;中国南部整层大气温度廓线在夏季风爆发后略有增加,对流层顶有所下降。     

Projected Shifts in Kppen Climate Zones over China and Their Temporal Evolution in CMIP5 Multi-Model Simulations

Previous studies have examined the projected climate types in China by 2100. This study identified the emergence time of climate shifts at a 1?scale over China from 1990 to 2100 and investigated the temporal evolution of K o¨ppen–Geiger climate classifications computed from CMIP5 multi-model outputs. Climate shifts were detected in transition regions(7%–8% of China's land area) by 2010, including rapid replacement of mixed forest(Dwb) by deciduous forest(Dwa) over Northeast China, strong shrinkage of alpine climate type(ET) on the Tibetan Plateau, weak northward expansion of subtropical winterdry climate(Cwa) over Southeast China, and contraction of oceanic climate(Cwb) in Southwest China. Under all future RCP(Representative Concentration Pathway) scenarios, the reduction of Dwb in Northeast China and ET on the Tibetan Plateau was projected to accelerate substantially during 2010–30, and half of the total area occupied by ET in 1990 was projected to be redistributed by 2040. Under the most severe scenario(RCP8.5), sub-polar continental winter dry climate over Northeast China would disappear by 2040–50, ET on the Tibetan Plateau would disappear by 2070, and the climate types in 35.9%and 50.8% of China's land area would change by 2050 and 2100, respectively. The results presented in this paper indicate imperative impacts of anthropogenic climate change on China's ecoregions in future decades.     

南亚夏季风爆发前后青藏高原地表热通量的长期变化特征分析

青藏高原作为世界第三极,其热力强迫作用不仅对亚洲季风系统的发展和维持十分重要,也会对大气环流场产生深远影响。利用欧洲中期天气预报中心（ECMWF）的ERA-Interim中1979-2016年3-10月青藏高原及其周边地区的地表热通量月平均再分析资料,通过分析得出以下结论:3-5月青藏高原主体由感热占据,感热强度快速上升且呈西高东低的分布态势,潜热强度较小但随时间而增强。季风爆发后的6-8月,青藏高原感热强度减弱,潜热强度迅速增强且呈东高西低的分布特征。季风消退后的9-10月,感热与潜热强度相当,但感热呈现出西高东低的分布特征。过去38年,青藏高原地表感热总体呈现微弱下降趋势,潜热呈较弱上升趋势。青藏高原西部地区感热呈微弱下降趋势,潜热呈上升趋势。东部感热呈较为明显的下降趋势且近年来变化趋势增强,东部潜热通量则呈现较为明显的上升趋势,分析结论与近期全球变暖条件下青藏高原气候变暖变湿这一变化状况一致,通过对青藏高原地表热通量的变化分析为下一步运用第三次青藏高原大气科学试验所获资料分析青藏高原上空大气热源的变化以及地表加热场如何影响大气环流奠定基础。      

青藏高原年降水的变化特征研究

青藏高原作为全球气候系统中的一个典型单元,它对全球气候变化的响应具有敏感性和强烈性。基于青藏高原135个台站1982～2001年的降水资料,利用EOF展开方法,分析青藏高原地区年降水的空间分布和时间演变特征及趋势变化,得出高原北区（青海地区）与南区（西藏地区）的年降水以南北反相变化为主。近20年来,青藏高原北区年降水量呈减少趋势,南区年降水量呈增加趋势,青藏高原年降水的分布自雅鲁藏布江河谷向西北逐渐递减,雅鲁藏布江下游地区降水最多,柴达木盆地西北部降水最少平均年降水量仅17.6mm。     

青藏高原土壤湿度时空分布特征研究进展

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。      

青藏高原影响亚洲夏季气候研究的最新进展

文中回顾了近 10a来吴国雄等在青藏高原影响亚洲夏季气候研究方面的最新进展。通过分析东西风交界面的演变证明 ,由于青藏高原的春季加热 ,亚洲季风区对流层低层冬季盛行偏东风转变为夏季偏西南风最早发生在孟加拉湾东部 ,与其相伴随的激烈对流降水出现在其东面。因此孟加拉湾东部至中印半岛西部是亚洲季风最早爆发的地区。同时也指出盛夏伊朗高原和青藏高原加热所激发的同相环流嵌套在欧亚大陆尺度的热力环流中 ,从而加强了东亚的夏季风 ,加剧了中西亚的干旱 ;并通过其所激发的波动对夏季东亚的气候格局产生重要影响。文中还比较了夏季南亚高压的伊朗模态和青藏模态性质的异同及其对亚洲夏季降水异常分布的不同影响。     

Accelerated climate change and its potential impact on Yak herding livelihoods in the eastern Tibetan plateau

The Tibetan Plateau has experienced rapid warming like most other alpine regions. Regional assessments show rates of warming comparable with the arctic region and decreasing Asian summer monsoons. We used meteorological station daily precipitation and daily maximum and minimum temperature data from 80 stations in the eastern Tibetan Plateau of southwest China to calculate local variation in the rates and seasonality of change over the last half century (1960–2008). Daily low temperatures during the growing season have increased greatly over the last 24 years (1984–2008). In sites of markedly increased warming (e.g., Deqin, Yunnan and Mangya, Qinghai), daily and growing season daily high temperatures have increased at a rate above 5 °C/100 years. In Deqin, precipitation prior to the 1980s fell as snow whereas in recent decades it has shifted to rain during March and April. These shifts to early spring rains are likely to affect plant communities. Animals like yaks adapted to cold climates are also expected to show impacts with these rising temperatures. This region deserves further investigation to determine how these shifts in climate are affecting local biodiversity and livelihoods.     

Assessment of vegetation dynamics and their response to variations in precipitation and temperature in the Tibetan Plateau

The Tibetan Plateau is a region sensitive to climate change, due to its high altitude and large terrain. This sensitivity can be measured through the response of vegetation patterns to climate variability in this region. Time series analysis of Normalized Difference Vegetation Index (NDVI) imagery and correlation analyses are effective tools to study land cover changes and their response to climatic variations. This is especially important for regions like the Tibetan Plateau, which has a complex ecosystem but lacks a lot of detailed in-situ observation data due to its remoteness, vastness and the severity of its climatic conditions. In this research a time series of 315 SPOT VEGETATION scenes, covering the period between 1998 and 2006, has been processed with the Harmonic ANalysis of Time Series (HANTS) algorithm in order to reveal the governing spatiotemporal pattern of variability. Results show that the spatial distribution of NDVI values is in agreement with the general climate pattern in the Tibetan Plateau. The seasonal variation is greatly influenced by the Asian monsoon. Interannual analysis shows that vegetation density (recorded here by the NDVI values) in the entire Tibetan Plateau has generally increased. Using a 1 km resolution land cover map from GLC2000, seven meteorological stations, presenting monthly data on near surface air temperature and precipitation, were selected for correlation analysis between NDVI and climate conditions in this research. A time lag response has also been found between NDVI and climate variables. Except in desert grassland (Shiquanhe station), the NDVI of all selected sites showed strong correlation with air temperature and precipitation, with variations in correlation according to the different land cover types at different locations. The strongest relationship was found in alpine and subalpine plain grass, the weakest in desert grassland.     

青藏高原前期冬春季地面热源与我国夏季降水关系的初步分析

首先对青藏高原地表热通量再分析资料与自动气象站(AWS)实测资料进行对比, 结果表明: 相对于美国国家环境预报中心和国家大气中心20世纪90年代研制的NCEP/NCAR(Kalnay 等1996)和NCEP/DOE (Kanamitsu 等2002) 再分析资料, ECMWF(Uppala 等2004)资料在高原地区的地表热通量具有较好的代表性。进一步利用奇异值分解(SVD)方法分析了ECMWF资料反映的高原地面热源与我国夏季降水的关系, 发现前期青藏高原主体的冬季地面热源与长江中下游地区夏季降水量呈负相关, 与华北和东南沿海地区的夏季降水量呈正相关。而长江中下游地区夏季降水量还与春季高原南部的地面热源存在负相关、与高原北部的地面热源存在正相关。高原冬、春季地面热源场的变化是影响我国夏季降水的重要因子。     

青藏高原隆升对亚洲季风形成和全球气候与环境变化的影响

综合介绍了青藏高原隆升对亚洲季风形成,半半球大气定常行星波建立,区域和全球气候变迁及环境演化的影响,并对近年来的研究进展作了较为详细的评述;指出今后需要深入研究的若干问题。     

青藏高原积雪对亚洲夏季风影响的诊断及数值研究

通过对青藏高原多、少雪年的合成分析及数值试验，研究了青藏高原积雪对亚洲 夏季风和我国东部气候异常的影响。结果表明:青藏高原积雪造成亚洲大气环流较大的年际变化。高原积雪改变了高原陆面春、夏季的热状况，使亚洲夏季风爆发推迟20天左右。高原积雪通过以下物理过程影响亚洲夏季风和我国东部气候:高原积雪多(少)→高原春、夏季的感热弱(强)→感热加热引起的上升运动弱(强)，高原强(弱)环境风场→不利(有利)于高原感热通量向上输送→高原上空对流层加热弱(强)→高原对流层温度低(高)→高原南侧温度对比弱(强)→造成亚洲夏季风弱(强)→我国长江流域易涝(旱)。     

ISCCP产品和我国地面观测总云量差异

国际卫星云气候计划ISCCP是国际上较权威和客观的云气候性研究计划, 自1983年以来为研究全球云和辐射平衡、云水资源分布等提供了有价值的数据。在分析总云量卫星和地面两种观测方式差异的基础上, 研究了1984-2006年ISCCP D2产品和我国地面观测云资料数据集总云量空间及时间差异。尽管两套资料能一致揭示我国总云量的分布形势和气候变化特征, 但区域性差异仍比较明显。天基、地基数据可对比格点上, 全国平均而言总云量卫星观测结果比地面观测偏高8.46%, 华南地区差异最小、东北地区差异最大。气候变化趋势分析结果表明:近23年我国总云量呈减少趋势, ISCCP D2产品总云量每年减少速度为0.015%, 小于地面观测的总云量每年减少速度 (0.063%); 东北地区总云量缓慢增多, 而青藏高原、西北地区总云量减少。利用卫星和地面资料均以累积距平法检测出1984—2001年总云量减少、2002-2006年总云量显著增加。