中国天山山区235 a气候变化及降水趋势预测

  利用4个降水重建序列与天山山区10个气象站降水变化的响应关系,重建了天山山区近235 a来气候变化的年降水序列,重建序列的方差解释量达到47.7%。对过去235 a天山山区气候变化中降水变化的特征分析发现：降水大致经历了7干7湿的变化阶段,其中偏湿年份为124 a,多于偏干年份;天山山区的降水量以2.1 a、3.0 a、5.8 a、6.0 a的高频变化和24~25 a的低频变化周期最为显著。研究表明,近百年天山山区气候变化中的降水变化分为两个阶段,20世纪初到80年代,降水量逐渐减少,导致冰川退缩、河流径流量减少、湖泊萎缩、沙漠面积增大、植被覆盖率减少;80年代后期至今,降水量迅速增加,导致河川径流量增加、湖泊面积增大和沙尘暴日数减少,生态环境趋于好转,但同时造成洪水和地质灾害频繁。采用基于方差分析的周期叠加方法对天山山区未来23 a气候变化中降水的演变趋势进行预测,结果表明：未来23 a气候变化中天山山区以湿润为主,期间有部分年份可能较常年干旱。     

华南冬春降水的年际变化及其与水汽输送的联系

利用1960—2008 年华南47 个基准站降水资料和NCEP/NCAR 再分析资料,研究了华南冬春降水的年际变化特征及其与水汽输送的联系。结果表明,1960 年代—1970 年代和1990 年代末至今,华南冬、春降水明显偏少。华南冬春降水异常以“ 全区冬春同号型” 居多,且冬春连旱频率较高。影响华南冬春连续旱/涝的水汽输送存在季节性差异,冬季水汽输送变化主要来源于孟加拉湾和南海,春季水汽输送变化则来源于南海和我国北方。进一步探讨海温异常的影响发现,与华南冬春连续旱(涝)事件相关的Niño3.4 海温存在正、负异常型,海温异常中心分别偏向Niño4(Niño3)区和Niño3(Niño4)区。Niño3.4 区海温正异常时,孟加拉湾和南海水汽输送与华南冬春连续旱涝有密切联系;Niño3.4 区海温负异常时,冬季自西北太平洋经南海的水汽输送及春季自菲律宾海经南海的水汽输送和北方水汽输送对华南冬春连续旱涝有重要影响。以上水汽输送在两种海温异常情况下,连涝(旱)年均异常偏强(弱)。因此,Niño3.4 海温异常的变化及分布与华南冬春持续旱/涝事件存在联系,在此气候背景下,水汽输送异常是影响华南冬春降水异常的重要物理因子,其中南海是水汽输送异常显著相关区。      

Quantifying the Spatial Characteristics of the Moisture Transport Affecting Precipitation Seasonality and Recycling Variability in Central Asia

Moisture contribution and transport pathways for Central Asia(CA)are quantitatively examined using the Lagrangian water cycle model based on reanalysis and observational data to explain the precipitation seasonality and the moisture transport variation during 1979-2015.Westerly-related(northwesterly and westerly)transport explains 42%of CA precipitation and dominates in southwest CA,where precipitation is greatest in the cold season.Southeast CA,including part of Northwest China,experiences its maximum precipitation in the warm season and is solely dominated by southerly transport,which explains about 48%of CA precipitation.The remaining 10%of CA precipitation is explained by northerly transport,which steadily impacts north CA and causes a maximum in precipitation in the warm season.Most CA areas are exposed to seasonally varying moisture transport,except for southeast and north CA,which are impacted by southerly and northerly transport year-round.In general,the midlatitude westerlies-driven transport and the Indian monsoon-driven southerly-related transport explain most of the spatial differences in precipitation seasonality over CA.Moreover,the contribution ratio of local evaporation in CA to precipitation exhibits significant interdecadal variability and a meridionally oriented tripole of moisture transport anomalies.Since the early 2000s,CA has experienced a decade of anomalously low local moisture contribution,which seems jointly determined by the weakened moisture contribution from midlatitudes(the Atlantic,Europe,and CA itself)and the enhanced contribution from high latitudes(West Siberia and the Arctic)and tropical areas(South Asia and the Indian Ocean).     

Precipitation cycles in the middle and lower reaches of the Yellow River (1736?2000)

Based on the long-term precipitation series with annual time resolution in the middle and lower reaches of the Yellow River and its four sub-regions during 1736?2000 recon-structed from the rainfall and snowfall archives of the Qing Dynasty, the precipitation cycles are analyzed by wavelet analysis and the possible climate forcings, which drive the precipita-tion changes, are explored. The results show that: the precipitation in the middle and lower reaches of the Yellow River has inter-annual and inter-decadal oscillations like 2?4a, quasi-22a and 70?80a. The 2?4a cycle is linked with El Ni?o events, and the precipitation is lower than normal year in the occurrence of the El Ni?o year or the next year; for the quasi-22a and the 70?80a cycles, Wolf Sun Spot Numbers and Pacific Decadal Oscillation (PDO) coincide with the two cycle signals. However, on a 70?80a time scale, the coincidence between solar activity and precipitation is identified before 1830, and strong (weak) solar activity is generally correlated to the dry (wet) periods; after 1830, the solar activity changes to 80?100a quasi-century long oscillation, and the adjusting action to the precipitation is be-coming weaker and weaker; the coincidence between PDO and precipitation is shown in the whole time series. Moreover, in recent 100 years, PDO is becoming a pace-maker of the precipitation on the 70?80a time scale.     

Cluster analysis on summer precipitation field over Qinghai–Tibet Plateau from 1961 to 2004

The summer day-by-day precipitation data of 97 meteorological stations on the Qinghai–Tibet Plateau from 1961 to 2004 were selected to analyze the temporal-spatial dis-tribution through accumulated variance, correlation analysis, regression analysis, empirical orthogonal function, power spectrum function and spatial analysis tools of GIS. The result showed that summer precipitation occupied a relatively high proportion in the area with less annual precipitation on the Plateau and the correlation between summer precipitation and annual precipitation was strong. The altitude of these stations and summer precipitation ten-dency presented stronger positive correlation below 2000 m, with correlation value up to 0.604 (α=0.01). The subtracting tendency values between 1961–1983 and 1984–2004 at five altitude ranges (2000–2500 m, 2500–3000 m, 3500–4000 m, 4000–4500 m and above 4500 m) were above zero and accounted for 71.4% of the total. Using empirical orthogonal function, summer precipitation could be roughly divided into three precipitation pattern fields: the Southeast Plateau Pattern Field, the Northeast Plateau Pattern field and the Three Rivers' Headstream Regions Pattern Field. The former two ones had a reverse value from the north to the south and opposite line was along 35°N. The potential cycles of the three pattern fields were 5.33a, 21.33a and 2.17a respectively, tested by the confidence probability of 90%. The station altitudes and summer precipitation potential cycles presented strong negative corre-lation in the stations above 4500 m, with correlation value of –0.626 (α=0.01). In Three Rivers Headstream Regions summer precipitation cycle decreased as the altitude rose in the sta-tions above 3500 m and increased as the altitude rose in those below 3500 m. The empirical orthogonal function analysis in June precipitation, July precipitation and August precipitation showed that the June precipitation pattern field was similar to the July’s, in which southern Plateau was positive and northern Plateau negative. But positive value area in July precipita-tion pattern field was obviously less than June’s. The August pattern field was totally opposite to June’s and July’s. The positive area in August pattern field jumped from the southern Pla-teau to the northern Plateau.     

基于TRMM数据的鄱阳湖流域降雨时空分布特征及其精度评价

基于1998-2007 年热带测雨卫星(TRMM) 3B42 V6 降雨数据分析鄱阳湖流域降雨时空分布特征, 并利用40个气象站观测日降雨数据对TRMM数据在不同子流域、不同降雨强度及不同季节里的精度进行了对比分析, 弥补了以往只评价整体精度的不足。结果显示:鄱阳湖流域北部地区修水、饶河子流域较易出现暴雨, 导致雷达信号衰减, 使TRMM对大雨强降雨的探测出现较大偏差;流域内降雨以10~50 mm为主, 其雨量占到总雨量的60%;流域降雨在年内1-3 月中旬为干旱少雨期, 3 月下旬-9 月初为湿润多雨期, 9-12 月再次进入干旱少雨期;而空间分布呈东、西部大, 中部小的格局;同时发现, 在赣南山区TRMM降雨较观测雨量低300~400 mm, 这可能受高程和坡度的影响, 使TRMM对山区降雨的探测精度也出现较大偏差。     

青藏高原全新世降水序列的集成重建

青藏高原全新世降水变化对于过去全球变化研究有重要意义。在过去全球变化研究中, 大尺度区域降水序列重建缺乏可行、有效的方法, 本文以青藏高原作为研究区, 构建了分区古降水空间模拟－多区面积加权的集成方法, 重建全新世青藏高原降水序列。本研究以孢粉为环境证据, 选取有空间代表性的10 条由孢粉重建的高原样点降水序列, 获得716 条具有年代的定量降水记录, 建立全新世古降水记录数据集。借助GIS分析, 基于现代高原降水空间分布的地理因子模拟, 并与古降水记录相集成, 定量重建了高原全新世200 年分辨率的降水序列。结果显示:早全新世高原降水迅速增多, 并在9.0 kaBP达到极大值500 mm, 较现代高170 mm;9.0~5.6 kaBP是旺盛的湿润期, 降水总体比现代高出80 mm, 但呈现明显的下降趋势;5.6 kaBP以来降水减少, 降水与现代相当, 但波动幅度较小;集成序列与其他高低分辨率环境记录有很好的可比性, 说明集成序列有很好的代表性和一定的准确性。     

IPCC A1B情景下中国西南地区气候变化的数值模拟

利用ECHAM5/MPI-OM 全球海气耦合模式模拟的当代(1986-2000 年)和IPCC A1B情景下未来(2011-2025 年)2×15a 的模拟输出格点场资料,驱动20 km高水平分辨率区域气候模式RegCM3 进行西南地区气候变化的数值模拟,主要分析未来地面温度和降水的可能变化。结果表明：①通过与32 个地面气象站观测资料和CRU资料对比分析,RegCM3 能够很好的模拟研究区基准时段地面温度和降水的局地分布特征。②A1B情景下未来西南地区年、四季平均温度均明显增加,北部温度变化幅度大于南部。③最高/最低温度一致升高,冬季最高/最低温度变化幅度大于夏季;年、秋冬季降水有所增加,冬季降水增加明显,而春夏季降水略有减少。④研究区未来春夏季温度升高、降水减少的趋势可能导致局部地区高温、干旱等极端天气的可能性增大;同时冬季降水增加,可能加重局部地区洪涝灾害的风险。     

面向对象的多特征分级CVA遥感影像变化检测

变化矢量分析CVA方法在中低分辨率遥感影像变化检测中已得到广泛应用,但由于高分辨率遥感影像存在不同地物尺度差异大、不同类别地物光谱相互重叠的问题,因此对于高分影像的变化检测具有局限性。为提高高分影像变化检测精度,提出了一种面向对象的多特征分级CVA变化检测方法,首先,利用基于区域邻接图的影像分割方法分别对两时相遥感影像进行多尺度分割,提取分割图斑的光谱、纹理和形状特征;然后,在各级尺度下,分别运用随机森林方法进行特征选择,计算CVA变化强度图;最后,根据信息熵对多级变化强度图进行自适应融合,利用Otsu阈值法检测变化区域,并与仅考虑光谱特征的分级CVA变化检测方法、像元级多特征CVA变化检测方法以及仅考虑光谱特征的像元级CVA变化检测方法进行比较分析。实验表明:与比较方法相比,本文方法的变化检测精度较高,误检率和漏检率较低。     

CMIP3与CMIP5模式对中国西北干旱区气温和降水的模拟能力比较

通过对15组CMIP3和CMIP5两代模式集合平均对中国西北干旱区气温和降水的模拟能力比较,发现CMIP5模式对气温和降水的模拟更接近观测值。CMIP5模式模拟年、春季、夏季、秋季平均气温的相关系数比CMIP3模式分别提升了0.15、0.13、0.24和0.02,冬季下降了0.07。CMIP5模式对西北干旱区的平均气温变化趋势的模拟效果比CMIP3有所提高,对年、春季、夏季、秋季、冬季趋势的模拟偏差比CMIP3分别减少了0.03℃/10a、0.10℃/10a、0.01℃/10a、0.06℃/10a、0.14℃/10a。对西北干旱区平均气温年、季的模拟偏差分布上,CMIP5模式的偏差均比CMIP3低1~2℃。但是天山区年、季节平均气温的模拟与整体模拟偏低情况相反,CMIP3和CMIP5分别偏高3~6℃和1~4℃,对夏季的模拟偏高最严重,分别达到6℃和4℃。CMIP5模式整体对西北干旱区降水量的模拟结果与观测值的平均相关系数与CMIP3相差不大,均不超过0.1,而且偏差仍然较大。CMIP5模式对西北干旱区的降水量的变化趋势模拟效果比CMIP3有所降低,对年、春季、夏季、秋季、冬季趋势的模拟偏差比CMIP3增加了0.67 mm/10a、0.23 mm/10a、0.51 mm/10a、0.11 mm/10a、0.14 mm/10a。CMIP5模式对年、春季、夏季、秋季和冬季的降水量模拟的均方根误差相比CMIP3分别减少77.6 mm、25.5 mm、25.0 mm、18.8 mm和13.9 mm。在空间上,CMIP5模式对年、季节降水模拟仍然偏高,但是比CMIP3有明显缓解;CMIP3和CMIP5模式对夏季天山区年降水量和夏季降水量的模拟也与大部分区域偏高的趋势明显相反,两代模式对夏季天山区的降水模拟均偏低50 mm左右。