Impacts of Climatic Factors on Runoff Coefficients in Source Regions of the Huanghe River

Runoff coefficients of the source regions of the Huanghe River in 1956–2000 were analyzed in this paper. In the 1990s runoff of Tangnaihai Hydrologic Station of the Huanghe River experienced a serious decrease, which had at- tracted considerable attention. Climate changes have important impact on the water resources availability. From the view of water cycling, runoff coefficients are important indexes of water resources in a particular catchment. Kalinin baseflow separation technique was improved based on the characteristics of precipitation and streamflow. After the separation of runoff coefficient (R/P), baseflow coefficient (Br/P) and direct runoff coefficient (Dr/P) were estimated. Statistic analyses were applied to assessing the impact of precipitation and temperature on runoff coefficients (including Dr/P, Br/P and R/P). The results show that in the source regions of the Huanghe River, mean annual baseflow coefficient was higher than mean annual direct runoff coefficient. Annual runoff coefficients were in direct proportion to annual pre- cipitation and in inverse proportion to annual mean temperature. The decrease of runoff coefficients in the 1990s was closely related to the decrease in precipitation and increase in temperature in the same period. Over different sub-basins of the source regions of the Huanghe River, runoff coefficients responded differently to precipitation and temperature. In the area above Jimai Hydrologic Station where annual mean temperature is –3.9oC, temperature is the main factor in- fluencing the runoff coefficients. Runoff coefficients were in inverse relation to temperature, and precipitation had nearly no impact on runoff coefficients. In subbasin between Jimai and Maqu Hydrologic Station Dr/P was mainly affected by precipitation while R/P and Br/P were both significantly influenced by precipitation and temperature. In the area be-tween Maqu and Tangnaihai hydrologic stations all the three runoff coefficients increased with the rising of annual precipitation, while direct runoff coefficient was inversely proportional to temperature. In the source regions of the Huanghe River with the increase of average annual temperature, the impacts of temperature on runoff coefficients be-come insignificant.     

A comprehensive analysis of phenological changes in forest vegetation of the Funiu Mountains,China

Journal of Geographical Sciences - This paper reports the phenological response of forest vegetation to climate change (changes in temperature and precipitation) based on Moderate Resolution...     

变暖背景下陕西极端气候事件变化分析

利用1961-2010年陕西省78个气象观测站的逐日最高温度、最低温度、平均温度以及日降水量资料,采用趋势分析方法对该地区极端气候事件的变化进行了分析。结果表明:①近50 a来陕西降水极端事件没有显著的增减变化趋势,但存在明显的阶段性。②近50 a来区域严重干燥事件在显著增加而严重湿润事件趋于减少,2000年以后严重干湿事件均偏多,区域降水有向不均衡、极端化发展的趋势。③区域年极端高（低）温事件在近50 a来呈现显著的增加（减少）趋势,其空间分布具有较好的一致性。极端温度事件的变化在各季节存在差异,冬、春季变暖的趋势比较显著。在显著变暖的20世纪90年代以后,相对于降水极端事件,温度极端事件显现地更为突出。     

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.     

新疆近50a来降水量时空变化及其突变分析

基于新疆53个气象台站1960—2005年逐月降水资料,通过Mann-Kendall非参数趋势检验方法,对新疆近50 a来年降水量和12个月降水量的趋势进行了分析,并计算12个月对年降水量的贡献率,同时通过SequentialMann-Kendall方法分析了27个台站年降水量显著增加趋势发生的时间突变点。结果表明,新疆近50 a来年降水量显著增加,北疆和南疆趋势最为明显;其中冬半年(1、2、11月和12月)这4个月的降水量增加趋势显著,对新疆年降水量的贡献较大;新疆大部分台站年降水量趋势发生突变的时间点在20世纪80年代以后。     

Lower Tropospheric Warm Air Advection Patterns Associated with Heavy Rainfall over the Appalachian Region*

A synoptic climatology of warm season heavy rainfall is developed from patterns of 850 mb thermal advection over the Appalachian region. Heavy rain events are categorized according to the position and orientation of a warm air advection (WAA) ridge, a feature found in nearly two-thirds of the events. Numerous study events occur within the conditionally unstable region of the WAA ridge. In fact, numerous occurrences of heavy rainfall are tied to a superpositioning of a WAA and air mass instability ridge in the vicinity or upstream of the heavy rain area.     

2011年春季中国北方沙尘天气过程及其成因

2011年春季,中国共出现了7次沙尘天气过程,其中沙尘暴4次,强沙尘暴2次,沙尘天气频次总体偏少、强沙尘暴偏多,影响范围较广。通过对2010/2011年冬季及2011年春季天气气候特征的分析表明:①2010/2011年冬季,冷空气偏强,气温偏低,有利于土壤冻结,同时新疆大部、内蒙古西部及东北部分地区降水偏少,使得前期地面植被状况偏差,进入2011年春季,中国北方大部地区降水仍偏少,地面植被状况虽未得到改善,但气温仍偏低,土壤解冻较晚,而2011年春季冷空气较常年偏弱,使得2011年沙尘暴发生时间较常年偏晚,且沙尘天气过程偏少;②中国北方沙尘天气常发区域土壤湿度较常年偏高,土壤状况良好,土质不够疏松,是2011年春季沙尘天气偏少的一个重要因素;③2011年春季蒙古国及内蒙古大部地区纬向风为偏西风的负距平区,不利于起沙及沙尘粒子向东输送。     

欧亚大陆积雪对我国春季气候可预报性的影响

利用江西省83个气象观测站1961—2018年春季(3—5月)逐日降水资料和NCEP/NCAR逐日再分析资料,对江西春季降水异常的大气环流特征及其对ENSO事件的响应进行了研究。结果表明：江西春季降水异常偏多年,中层500 hPa中高纬地区受欧亚型环流(EU型)影响,乌拉尔山附近阻塞高压系统活动频繁,贝加尔湖地区低槽偏强,西太平洋副热带高压(简称西太副高,下同)偏强,有利于北方冷空气南下并与偏南暖湿气流在江西上空交汇;低层850 hPa菲律宾以东西太平洋地区为异常反气旋环流控制,造成南海水汽向江西地区输送加强。而江西春季降水异常偏少年,其环流特征表现则与之相反。ENSO是影响江西春季降水的重要强迫信号,厄尔尼诺(拉尼娜)衰减年,春季东亚地区低层850 hPa西太副高偏强(弱),有(不)利南海上空水汽向江西地区输送,低层辐合(辐散)和高层200 hPa辐散(辐合)形成的动力抬升条件是造成江西地区降水偏多(少)的主要原因。

     

末次间冰期127 ka时期植被反馈增强东亚夏季风降水的数值模拟研究

黄土和石笋等古气候代用资料表明在末次间冰期间,东亚夏季风增强、降水增多。本研究利用地球系统模式EC-Earth模拟了末次间冰期127 ka时期的气候,通过和工业革命前的气候模拟控制试验做比对,分析了127 ka时期由于地球轨道参数变化导致的东亚夏季风的空间变化特征。我们利用了两种EC-Earth的模式配置,即"大气-陆面-海洋-海冰"耦合模式和"大气-陆面-海洋-海冰-动态植被"耦合模式,分别估算轨道强迫和植被反馈对东亚夏季风降水变化的贡献。数值模拟结果表明,地球轨道强迫导致的海陆热力差异使得东亚夏季风系统显著增强并北移西伸,中国中部及华北地区降水增多而东部沿海地区降水减少。耦合了动态植被模式的试验结果表明,127 ka时期温暖湿润的气候致使东亚地区植被增多,植被的蒸腾作用使得地表的感热和潜热通量显著增大,从而增强了局地水循环,使降水进一步增多。植被的反馈作用在原本温暖湿润的华南地区对降水的影响并不显著,但是对相对干旱的我国中部和华北地区降水有显著影响。数值试验结果表明轨道强迫和植被反馈的共同作用能使内陆的四川盆地到华北一带夏季降水增加约40%,其中30%的增加是由于轨道强迫作用,约10%是由于植被反馈。这个研究也提醒我们,要得到更加合理的对过去或未来气候变化的模拟结果,有必要使用耦合动态植被的气候系统模式。

     

古尔班通古特沙漠南缘丘间地梭梭群落蒸散特征

根据2016年古尔班通古特沙漠南缘丘间地梭梭生育期定点观测的土壤水分、气象要素等资料,基于水量平衡原理估算了梭梭生育期蒸散量,分析了蒸散变化规律。结果表明：（1）在梭梭生长季,降雨量为206.7 mm,降雨分布不均,梭梭萌发期,降雨量最多;梭梭生长旺盛期,月降雨量逐月减少;梭梭枯落期,降雨量最少。（2）在梭梭生长季,梭梭群落0~400 cm土壤贮水量变化整体呈下降趋势,梭梭萌发期是土壤贮水量盈余期,生长旺盛期和枯落期为土壤贮水量亏损期;梭梭群落发挥土壤水库效应,依靠生长季前土壤蓄水来弥补梭梭群落生长季需水缺额。（3）在梭梭生长季,蒸散量变化特征为多峰曲线,峰值主要出现在降雨集中期,最低值出现在土壤贮水量亏损期。（4）在梭梭生长季,梭梭群落累积蒸散量增幅始终高于累积降雨量增幅,累积蒸散量大于累积降雨量。