Satellite-measured water vapor isotopologues across the Tianshan Mountains,central Asia

The satellite-based water vapor stable isotope measurements have been widely used in modern hydrological and atmospheric studies. Their use is important for arid areas where the precipitation events are limited, and below-cloud evaporation is strong. This study presents the spatial and temporal characteristics of water vapor isotopologue across the Tianshan Mountains in arid central Asia using the NASA Aura Tropospheric Emission Spectrometer (TES). The near-surface water vapor stable isotopes are enriched in summer and depleted in winter, consistent with the seasonality of precipitation isotopes. From the surface to 200 hPa, the isotope values in water vapor show a decreasing trend as the atmospheric pressure decreases and elevation rises. The vapor isotope values in the lower atmosphere in the southern basin of the Tianshan Mountains are usually higher than that in the northern basin, and the seasonal difference in vapor isotopes is slightly more significant in the southern basin. In addition, bottom vapor isotopologue in summer shows a depletion trend from west to east, consistent with the rainout effect of the westerly moisture path in central Asia. The isotopic signature provided by the TES is helpful to understand the moisture transport and below-cloud processes influencing stable water isotopes in meteoric water.     

阿尔泰山降水氢氧稳定同位素特征及水汽来源分析

阿尔泰山横亘于亚欧大陆中部,是中纬度西风带气候研究的重点区域之一。利用阿尔泰山地区4个站点的监测数据,研究了该区域降水氢氧稳定同位素的年内变化特征及大气降水线方程,分析了降水同位素的温度效应,并利用后向轨迹探讨了水汽来源。结果表明：（1） 阿尔泰山各站点降水同位素比率在季节上表现为夏高冬低,且南侧站点的季节差异比北侧大,除Novosibirsk外大多数站点的降水氘盈余值为夏低冬高。（2） 除Novosibirsk外,研究区大多数站点大气降水线方程的斜率和截距都低于全球平均值。（3） 各站点降水同位素存在明显的温度效应,体现在季节变化和空间分布上。（4） 后向轨迹表明,研究区受到西风水汽、极地水汽和近源水汽路径的影响,且偏北站点可能受极地水汽路径的影响更大。上述认识有助于明确阿尔泰山不同区域降水同位素时空变化反映的水文气候信息,并为该区域大气水循环及气候变化研究提供参考。     

印度河上游Bagrot山谷降水稳定同位素变化及与水汽来源的关系

利用2015年8月至2016年7月在印度河上游流域Bagrot山谷降水稳定同位素（δ18O和δD）观测结果以及当地气象资料，利用同位素示踪及统计分析方法，并结合HYSPLIT模型，对研究区降水稳定同位素变化特征、大气水线以及水汽来源进行了分析。结果表明，观测期间Bagrot山谷降水稳定同位素的季节变化明显，δ18O与δD秋冬季偏低，春夏季偏高，且与气温变化一致，存在显著的温度效应，而降水量效应不明显。而且发现，研究区局地大气水线截距和斜率均低于全球的，反映了降水过程中云下二次蒸发作用较为强烈，特别是，不同的降水形态导致该研究区局地大气水线的斜率和截距不同。当液态降水（降雨）发生时，由于在较为干旱的气候环境下，雨滴在降落的过程中受到二次蒸发相对较强，使得局地大气水线的斜率和截距偏低；而当固态降水（降雪）发生时，由于温度较低，受再循环水汽和二次蒸发的影响较小，导致局地大气水线的斜率和截距均偏高。Bagrot山谷及其周边地区，从南到北局地大气水线的斜率相差不大，而其截距总体上随着纬度升高而降低，可能与云下二次蒸发导致稳定同位素发生的不平衡分馏逐渐强烈有关。通过Bagrot山谷站点降水稳定同位素观测结果并结合HYSPLIT模型的后向追踪，研究还发现，研究区全年主要受西风环流以及局地环流的影响。但与研究区以北的临近站点（慕士塔格、和田等）相比有所不同，由于Bagrot山谷位置更靠南，其仍然偶尔受到来自南方的海洋性水汽影响。这一研究结果可能对该地区树轮稳定同位素记录的解译具有一定的指示意义。     

A review of precipitation isotope studies in China: Basic pattern and hydrological process

In the paper, the development of precipitation isotope observation networks in China was reviewed, and recent achievements in isoscape and environmental effect of precipitation stable isotopes were summarized; the hydrological process studies based on precipitation isotopes in China during recent decade were also reviewed. In past decades, the spatial and seasonal patterns of precipitation isotopes have been investigated nationwide, especially after the participation in GNIP (Global Network of Isotopes in Precipitation) and the establishment of CHNIP (Chinese Network of Isotopes in Precipitation), although long-term measurements are still limited; besides the nationwide network, a series of regional networks has been widely established across China. From the traditional manual drawing to the computer- aided mapping, and then to the simulation using isotope-equipped models, the productions of precipitation isoscape have been improved. The main factors controlling precipitation isotopes were summarized, and the potential significances of isotopes in climate proxies were mentioned. The recent studies about influence of raindrop sub-cloud secondary evaporation on isotopes were reviewed; based on the precipitation isotope and other parameters, the contribution of recycled moisture (evaporation and transpiration) in local precipitation can be estimated using three- or two-component mixing models. Finally, some prospects of precipitation isotope studies in China were presented.     

新疆夜雨和昼雨的空间分布和长期变化

用新疆98个气象站1960—2001年的昼夜降水量资料,分析了冷季（10月到翌年3月）和暖季（4—9月）昼夜降水频率和强度的差异和空间分布。结果表明：新疆暖季分别有两个频率≥55％的夜雨区和昼雨区。夜雨区分别位于西天山北坡和西昆仑山北坡;昼雨区位于阿尔泰山南坡和天山南坡等地。而到了冷季,暖季夜雨和昼雨的条状带相间的格局消失。除了海拔较高的西天山山区和海拔较低的塔里木盆地西部、吐善托盆地分别有小范围的夜雨区和昼雨区外,新疆其他地区的夜雨和昼雨的比例均在45％~55％之间,基本趋于平衡,夜雨和昼雨之差较暖季已明显减弱。对于暖季的大降水事件（一个夜间或白天降水>15 mm）,伊犁河谷、中东天山及天山北坡,昆仑山北坡60％以上发生在夜间,阿尔泰山和塔尔巴哈台南坡、天山东南部盆地地区60％以上发生在白天。另外,还对暖季夜雨区夏季降水的长期变化进行了分析,结果显示,这两个以夜间降水为主的区域,其夜间降水的增加率略大于白天,并不是很明显大于白天降水的增加率。     

中国的降水同位素研究——基本特征与水文过程（英文）

In the paper, the development of precipitation isotope observation networks in China was reviewed, and recent achievements in isoscape and environmental effect of precipitation stable isotopes were summarized; the hydrological process studies based on precipitation isotopes in China during recent decade were also reviewed. In past decades, the spatial and seasonal patterns of precipitation isotopes have been investigated nationwide, especially after the participation in GNIP(Global Network of Isotopes in Precipitation) and the establishment of CHNIP(Chinese Network of Isotopes in Precipitation), although long-term measurements are still limited; besides the nationwide network, a series of regional networks has been widely established across China. From the traditional manual drawing to the computer-aided mapping, and then to the simulation using isotope-equipped models, the productions of precipitation isoscape have been improved. The main factors controlling precipitation isotopes were summarized, and the potential significances of isotopes in climate proxies were mentioned. The recent studies about influence of raindrop sub-cloud secondary evaporation on isotopes were reviewed; based on the precipitation isotope and other parameters, the contribution of recycled moisture(evaporation and transpiration) in local precipitation can be estimated using three- or two-component mixing models. Finally, some prospects of precipitation isotope studies in China were presented.     

西北干旱区山区融雪期气候变化对径流量的影响

利用8 个山区气象站1960-2010 年日平均气温、降水和7 个出山口水文站的年径流数据(1960-2008), 统计分析了山区融雪期开始时间、结束时间、天数、温度和降水的变化趋势及其空间差异性, 并定量评估了年径流量对融雪期温度和降水变化的敏感性。结果表明, 近50年来, 山区融雪期平均提前了15.33 天, 延迟了9.19 天;其中, 天山南部山区融雪期提前时间最长, 为20.01 天, 而延迟时间最短, 仅6.81 天;祁连山北部山区融雪期提前时间最短(10.16天), 而延迟时间最长(10.48 天)。这显示山区融雪期提前时间越长, 延迟时间则越短。山区融雪期平均降水量增加了47.3 mm, 平均温度升高了0.857℃;其中天山南部山区降水增量最大, 达65 mm, 昆仑山北部山区降水和温度增量均最小, 分别为25 mm和0.617℃, 而祁连山北部山区温度增量最高(1.05℃)。河流径流量对融雪期气候变化敏感, 降水变化诱发年径流量变化了7.69%, 温度变化使得年径流量改变了14.15%。     

西北地区山区融雪期气候变化对径流量的影响(英文)

Water resources in the arid land of Northwest China mainly derive from snow and glacier melt water in mountainous areas. So the study on onset, cessation, length, tempera-ture and precipitation of snowmelt period is of great significance for allocating limited water resources reasonably and taking scientific water resources management measures. Using daily mean temperature and precipitation from 8 mountainous weather stations over the pe-riod 1960?2010 in the arid land of Northwest China, this paper analyzes climate change of snowmelt period and its spatial variations and explores the sensitivity of runoff to length, temperature and precipitation of snowmelt period. The results show that mean onset of snowmelt period has shifted 15.33 days earlier while mean ending date has moved 9.19 days later. Onset of snowmelt period in southern Tianshan Mountains moved 20.01 days earlier while that in northern Qilian Mountains moved only 10.16 days earlier. Mean precipitation and air temperature increased by 47.3 mm and 0.857℃ in the mountainous areas of Northwest China, respectively. The precipitation of snowmelt period increased the fastest, which is ob-served in southern Tianshan Mountains, up to 65 mm, and the precipitation and temperature in northern Kunlun Mountains increased the slowest, an increase of 25 mm and 0.617℃, respectively, while the temperature in northern Qilian Mountains increased the fastest, in-creasing by 1.05℃. The annual runoff is also sensitive to the variations of precipitation and temperature of snowmelt period, because variation of precipitation induces annual runoff change by 7.69% while change of snowmelt period temperature results in annual runoff change by 14.15%.     

基于Copula 函数的新疆极端降水概率时空变化特征

依据新疆地区53 个雨量站1957-2009 年日降水资料,根据研究需要,定义了8 个极端降水指标。运用K-S 法确定降水指标最适概率分布函数,确定十年一遇极端降水量值;在此基础上,采用Copula 非参数估计方法,通过Akaike Information Criterion (AIC) 法确定两降水指标联合分布函数,系统分析极端降水单变量极值及降水极值二维联合概率分布特征,研究新疆地区降水极值概率变化的空间演变特征。研究结果表明：(1) 北疆比南疆湿润,北疆发生极端强降水的概率大,而南疆发生极端弱降水的概率较大,另外,相比较而言,山区要比平原降水多;(2) 极端强、弱降水同年发生的概率分布特征复杂,从降水天数来看,一年内同时发生长历时强降水与弱降水事件的概率山区较平原大;从极端降水总量来看,同时发生强降水与弱降水事件的概率在平原区较山区为大;从极端降水强度来看,同时发生强度较大的强降水与弱降水事件的概率在天山南坡较其他地区为大;(3) 洪旱发生概率与地形有关,天山是洪旱发生的分界线,山区发生洪旱灾害的概率比平原小。     

TRMM降水数据在中天山区域的精度评估分析

 遥感降水产品能反映降水的时空分布变化,对于资料稀缺的西北干旱区生态水文研究有重大意义。TRMM卫星降水资料在热带湿润地区有大量应用,但要将其用于我国西北干旱半干旱气候地区,还需对该数据产品在质量进行评估。选择干旱区内陆的新疆天山中部为研究区,并以周边15个台站的实测数据为依据对TRMM3B42降水数据质量进行评价。结果表明：（1）TRMM3B42数据对日降水事件的估计准确率较低,但是总体上暖季好于冷季,相对于较大的降水,对发生量小的降水估计更为准确;在暖季高估量小降水,低估量大降水,冷季则相反;（2）月降水情况来看,天山南坡两站与北坡的规律不符;对北坡山区降水估计的精度好于平原区,并且精度与海拔呈抛物线分布,降水越大的区域精度越高;偏差量的年内分布在各海拔区域之内一致性较好,但区域之间规律各有特点;（3）从年降水量来看,TRMM降水整体低于站点观测值,并且差量随着高程具有抛物线分布的特征。总之,该降水产品的质量总体上不高,但是其偏差在时间和空间上具有一定的规律性,该数据在干旱区的应用需要进一步校准处理。     

基于CLM模型的月尺度中亚陆表蒸散和土壤水分模拟估算

论文基于CLM 4.5模拟1980—2009年月尺度中亚陆表蒸散发和土壤水分,并和GLDAS、GLEAM数据产品进行对比,结果表明CLM 4.5模拟的蒸散和土壤水分区域平均值和其他产品具有较好的一致性。从CLM 4.5模拟的陆表蒸散结果分析可知：全年蒸散大部分集中于春夏2季,在5月达到一年的最大值,夏季中亚的蒸散高值区集中在哈萨克斯坦北部和东北部、东南部的山地区,对应主要的农田区和林地区,植被蒸腾占主导因素;春季东南部天山山脉和帕米尔高原是蒸散高值区,主要因为该地区春季降水量较大,且积雪开始融化,水量充足,地表蒸散发充分;蒸散低值区主要在西南的土库曼斯坦和乌兹别克斯坦,地表覆盖以荒漠为主,植被覆盖较少,降水也较少,导致地面蒸散量较低。模拟的表层土壤水分结果表明：冬季陆面蒸散低,降水大多储存在表层土壤内或者以积雪的形式覆盖在地面上,春季气温升高,积雪融化下渗到土壤中,土壤水分持续增加,4月份达到峰值;夏季蒸散增加,降水减少,土壤水分持续下降,9月份达到最低值;进入秋冬季后蒸散降低,土壤水分呈上升趋势。中亚土壤水分高值区集中在北部和东北部的林地、农田区,以及天山山脉和下游的阿姆河、锡尔河流域区,西南部的荒漠区依然是低值区。一年中,夏季降水较少,由于地面蒸发的作用,土壤水分持续较少,蒸散也随之降低。三者之间相关性很高;冬季降水和土壤之间的相关性较高,尤其是裸地区;在植被覆盖较大的情况下,春季降水和蒸散相关性较高,土壤水分和降水、蒸散之间相关性较低,会出现负相关情况。CLM 4.5模拟的结果为进一步中亚地区的水问题研究奠定基础。     

黄河流域降水稳定同位素的云下二次蒸发效应

雨滴从云底降落到地面过程的云下二次蒸发现象会影响雨滴中的同位素比率，明确降水过程中稳定同位素的变化对研究流域水循环具有重要意义。基于全球降水同位素网络（GNIP）、相关文献同位素数据以及气象数据，首先建立局地大气水线（LMWL）定性分析了黄河流域云下二次蒸发与各气象要素间的关系，其次运用改进的Stewart模型定量计算了蒸发剩余比（f）和云底降水与地面降水的D-excess之差（Δd）。结果表明：（1） 黄河流域LMWL方程为：δ²H=7.01δ¹⁸O+1.25（n=293，R²=0.92），斜率和截距相比GMWL均较小，说明雨滴在下落过程中受到云下二次蒸发的影响。其中0～10 mm的降雨事件对云下二次蒸发影响显著；气温越高，或者水汽压、相对湿度越小，云下二次蒸发越强烈。（2） 季节变化上，从春季到冬季， f和Δd逐渐增大，云下二次蒸发逐渐减小。空间变化上，蒙甘区、蒙中区、晋陕甘区和渭河区的西安，年际间云下二次蒸发变化较大，而青南区、祁连-青海湖区、渭河区的平凉、长武、华山和鲁淮区年际差异较小。（3） 降水中Δd和f之间的线性关系在不同气象要素范围内有不同的数值，由于不同区域各气象条件存在差异，因此在应用经验公式时需考虑研究区的具体气象条件。     

长沙地区蒸发皿水体蒸发过程中稳定同位素的变化特征

蒸发过程中水体同位素分馏与蒸发时的气象要素密切相关。为此,于2013年6―9月份在长沙地区进行了4组室外蒸发皿蒸发实验,从而探讨蒸发剩余水体中稳定同位素与温度、相对湿度等气象要素之间的关系。实验结果表明：1）剩余水体中稳定同位素比率随着剩余水比例f的减少而富集,在高温无雨的伏旱天气下,蒸发剩余水体中稳定同位素分馏结果与瑞利分馏模式比较吻合;2）温度越高,分馏效应也将变大,蒸发过程中稳定同位素比率的改变量也将变大,随着水体质量的减小,稳定同位素比率的变化与相对湿度呈现负相关,尤其到蒸发后期,负相关关系更为明显,这可能是由于实验后期剩余水体绝对质量太小,易受空气中稳定同位素的影响;3）蒸发线δ2H＝3.89δ18O－24.55与δ2H＝3.38δ18O－24.96的斜率和截距明显小于同时期长沙降水线δ2H＝6.85δ18O－4.4的斜率和截距,与同时期湘江河水蒸发线δ2H＝3.9δ18O－13.2的斜率接近。以上结果说明本蒸发皿实验能一定程度上体现夏季自然水体蒸发分馏情况。     

Sensitivity and areal differentiation of vegetation responses to hydrothermal dynamics on the northern and southern slopes of the Qinling Mountains in Shaanxi province

The Qinling Mountains, located at the junction of warm temperate and subtropical zones, serve as the boundary between north and south China. Exploring the sensitivity of the response of vegetation there to hydrothermal dynamics elucidates the dynamics and mechanisms of the main vegetation types in the context of changes in temperature and moisture. Importance should be attached to changes in vegetation in different climate zones. To reveal the sensitivity and areal differentiation of vegetation responses to hydrothermal dynamics, the spatio-temporal variation characteristics of the normalized vegetation index(NDVI) and the standardized precipitation evapotranspiration index(SPEI) on the northern and southern slopes of the Qinling Mountains from 2000 to 2018 are explored using the meteorological data of 32 meteorological stations and the MODIS NDVI datasets. The results show that: 1) The overall vegetation coverage of the Qinling Mountains improved significantly from 2000 to 2018. The NDVI rise rate and area ratio on the southern slope were higher than those on the northern slope, and the vegetation on the southern slope improved more than that on the northern slope. The Qinling Mountains showed an insignificant humidification trend. The humidification rate and humidification area of the northern slope were greater than those on the southern slope. 2) Vegetation on the northern slope of the Qinling Mountains was more sensitive to hydrothermal dynamics than that on the southern slope. Vegetation was most sensitive to hydrothermal dynamics from March to June on the northern slope, and from March to May(spring) on the southern slope. The vegetation on the northern and southern slopes was mainly affected by hydrothermal dynamics on a scale of 3–7 months, responding weakly to hydrothermal dynamics on a scale of 11–12 months. 3) Some 90.34% of NDVI and SPEI was positively correlated in the Qinling Mountains. Spring humidification in most parts of the study area promoted the growth of vegetation all the year round. The sensitivity of vegetation responses to hydrothermal dynamics with increasing altitude increased first and then decreased. Elevations of 800 to 1200 m were the most sensitive range for vegetation response to hydrothermal dynamics. The sensitivity of the vegetation response at elevations of 1200–3000 m decreased with increasing altitude. As regards to vegetation type, grass was most sensitive to hydrothermal dynamics on both the northern and southern slopes of the Qinling Mountains; but most other vegetation types on the northern slope were more sensitive to hydrothermal dynamics than those on the southern slope.     

沙漠绿洲-高山冰雪气候带的垂直变化特征研究

气候变化在垂直方向上的分布规律是气候变化研究的一个重要方面。利用在天山北坡中部径向剖面上的6个不同海拔高度的气象站的气象资料,研究了沙漠绿洲-高山冰雪气候带在冬季、夏季和年度的年际气候变化对高度的响应,指出20世纪90年代(1991-2000)与前30 a(1961-1990)相比,平均气温、年降水量增加幅度随高度呈现非线性变化,不论在哪个高度上,冬季的增温幅度都要大于夏季;在最靠近沙漠的低海拔地区,年降水量增加幅度并不是最大的,而在海拔较高的山前绿洲地带和在3 500 m的高山区降水量增幅相对较大。此外,对气温、降水、相对湿度、蒸发等气候因子的变化趋势倾向率进行了分析,比较了不同高度的线性倾向率,揭示了沙漠绿洲边缘至高山冰雪带的气候变化在垂直方向上的分布特征,表明不论在哪个高度上,冬季、夏季和年度的平均气温变化都具有上升趋势;在山前地带和高海拔山区,降水增加趋势相对明显;蒸发能力减弱,相对湿度增加。     

台风“海马”对洞庭湖流域降水同位素的影响研究

基于2011年第4号台风“海马”登陆前后洞庭湖流域内长沙降水同位素资料,分析了降水同位素的变化特征以及水汽输送对降水同位素的影响。结果表明：台风“海马”在洞庭湖流域内长沙所形成降水的大气水线的斜率和截距均小于长沙夏季大气水线,这与根据同位素分馏理论做出的推测相吻合。台风天气系统影响下的流域降水δ ¹⁸O值为研究时段内的最低值,即降水同位素被显著贫化,而降水过量氘（deuterium excess,记为d）波动明显要小于其他时段,后者反映了形成台风降水的水汽来源较为单一。研究时段内长沙降水d指示台风降水前、台风降水中两个阶段水汽来源于西太平洋,水汽输送轨迹也印证了降水d所指示的水汽来源情况,如流域台风降水的水汽主要来自前期台风输送至南海北部的西太平洋水汽。台风降水后这一阶段降水中d指示海洋水汽来源的效果降低,其原因在于海洋水汽输送减少、陆地蒸发旺盛以及下落雨滴蒸发强烈所致。     

天山冰川资源及其分布规律

本文从天山冰川数量，冰储量、类型以及分布特征等方面系统地分析了天山冰川的资源及其分布规律，为经济建设提供可靠的山地水资源论据。     

祁连山东部大气降水分δ17O变化特征及水汽输送

祁连山作为我国西部重要生态安全屏障，是河西走廊内陆河流域核心水源区。通过测定2013年7月~2014年7月收集的降水样品中δ¹⁷O与δ¹⁷O值，分析了祁连山东部乌鞘岭大气降水中δ¹⁷O的特征，在此基础上对水汽来源进行了研究。结果表明：降水稳定同位素¹⁷O存在夏高冬低的变化特征；¹⁷O存在显著的温度效应而不存在降水量效应，¹⁷O与水汽压在干季呈现正相关关系。研究区大气降水的氧同位素降水线方程为：δ′¹⁷O = 0.509δ′¹⁷O -0.16，低于氧同位素全球降水线斜率；过量δ¹⁷O表现出夏低冬高的特点；综合分析氧同位素大气降水方程线和过量δ¹⁷O变化，发现该区域大气降水主要受局地水循环和大陆气团控制。祁连山东部地区主要受到西风和东南季风携带水汽影响，东南季风携带水汽对于祁连山东部的影响主要集中于夏季。研究可提高对祁连山区降水同位素演化的认知，为寒旱区同位素水文学的进一步研究奠定基础。     

海河流域降水稳定同位素的云底二次蒸发效应

云底二次蒸发导致的同位素动力分馏可显著影响观测的降水同位素组成和大气水线。本文利用海河流域7个监测站点的降水δ²H和δ¹⁸O数据,分析了云底二次蒸发对流域降水同位素的影响。结果表明：流域降雨水样的大气水线为δ²H=7.19δ¹⁸O-0.74,显著不同于降雪水样的大气水线(δ²H=8.42δ¹⁸O+15.88);流域降雨,特别是小降雨(<5 mm)事件,易受到云底二次蒸发的影响,导致其大气水线的斜率和截距均随着降雨量的减小而减小。流域降雨同位素的云底二次蒸发主要受气温和相对湿度控制,随着气温的升高和相对湿度的减小,云底二次蒸发加剧,导致观测的地面降雨富集重的同位素,同时伴随的同位素动力分馏导致流域降水过量氘(d)值以及大气水线的斜率和截距均减小。与平原地区相比较,流域山间盆地地区受“雨影效应”影响,气候相对干燥,其降雨同位素受更强的云底二次蒸发影响。观测期间,流域小的降雨事件占总降水事件的42%,故云底二次蒸发对流域降水同位素具有重要的影响。     

基于GIMMS AVHRR NDVI数据的三北防护林工程区植被覆盖动态变化与影响因子分析研究(英文)

本文基于1982-2006年连续25年的GIMMS AVHRR NDVI植被覆盖指数,采用了最大化NDVI均值法、与气温及降水变化的相关性和一元线性回归趋势分析法,对中国三北防护林工程区连续25年的植被覆盖时空变化特征进行了动态变化研究。结果表明:(1)近25年来,研究区植被NDVI平均值总体呈缓慢上升趋势,增速为每10年0.007;(2)研究区植被和气温、降水整体呈正相关关系,植被与降水正相关面积明显大于植被与气温正相关面积,说明降水是研究区植被生长的关键因子;(3)1982-2006年,研究区植被覆盖增加的区域主要分布在大兴安岭中、南部,小兴安岭中部,长白山东北段,燕山,辽西低山丘陵区,阿尔泰山,天山,祁连山东段,西北荒漠区东部和黄土高原丘陵沟壑区南部等;植被覆盖减少的区域主要是在大兴安岭两侧,呼伦贝尔高原西部,三江平原北部,科尔沁沙地南端,西北荒漠区南部和黄土高原丘陵沟壑区北部等。