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1.
Climatic implications of hydrologic changes in two lake catchments on the central Tibetan Plateau since the last glacial 总被引:1,自引:0,他引:1
The numerous and widespread lakes of the Tibetan Plateau (TP) constitute the largest group of alpine lakes on Earth. Some of the lakes are fed mainly by glacier meltwater and others by precipitation and groundwater. Past changes in the environments of these lakes differed because of differences in lake hydrological regimes and the complex pattern of climate change on the TP. Here we present records of scanning XRF, inorganic carbon (IC) concentration n-alkanoic acid average chain length (ACL) and percent aquatic inputs (Paq) in sediment cores from two non-glaciated lakes on the central TP (Dagze Co and Jiang Co), which span the past 19,000 years. We used these measures to investigate past changes in catchment hydrology, climate and environment. Variations in the concentration of Ti and other lithogenic elements at the two sites were influenced mainly by surface runoff, which is supported by the variation of IC, Ca/(Al, Ti, Fe) (reflecting authigenic carbonate precipitation), Rb/Sr (a chemical weathering proxy), and ACL and Paq. We attribute variations in surface runoff to changes in the precipitation/evaporation ratio, caused by the pattern of climate change on the central TP since the late Pleistocene. During the late Pleistocene, stronger runoff (indicated by higher Ti, higher Rb/Sr and Paq, lower IC, Ca/(Al, Ti, Fe) and ACL) likely resulted from lower temperatures. Lower runoff during the Holocene may reflect intensified evaporation caused by higher temperatures. Comparison with records from glaciated lakes in the region reveals opposite trends in catchment hydrology. Overall, our results suggest that since the late Pleistocene the central TP was influenced mainly by the Indian Summer Monsoon. 相似文献
2.
Isotopic evolution and climate paleorecords: modeling boundary effects in groundwater-dominated lakes 总被引:1,自引:0,他引:1
We used an isotopic mass-balance model to examine how the hydrogeologic setting of lakes influences isotopic response of evaporating
lake water to idealized hydroclimatic changes. The model uses a monthly water and isotope balance approach with simplified
water-column structure and groundwater exchanges. The framework for comparative simulations is provided by lakes in a region
of the Northern Rocky Mountains that display high interlake geochemical variability, thought to be controlled by groundwater
hydraulics. Our analysis highlights several isotopic effects of flow between aquifers and lakes, leading to possible divergence
of isotopic paleorecords formed under a common climate. Amplitude of isotopic variation resulting from simulated climate forcing
was greatly damped when high groundwater fluxes and/or low lake volume resulted in low lake fluid residence time. Differing
precipitation and evaporation scenarios that are equivalent in annual fluid balance (P−E) resulted in different isotopic signatures,
interpreted as a result of evaporation kinetics. Concentrating low-δ groundwater inflow during spring months raised springtime
lake δ values, a counterintuitive result of coincidence between times of high groundwater inflow and the evaporation season.
Transient effects of reduced fluid balance caused excursions opposite in sign from eventual steady-state isotopic shifts resulting
from enhanced groundwater inflow dominance. Lags in response between climate forcing and isotopic signals were shortened by
high groundwater fluxes and resulting short lake residence times. Groundwater-lake exchange exerts control over patterns of
lake isotopic response to evaporation through effects on lake residence time, inflow composition, and seasonal timing of inflow
and outflow. Sediments from groundwater-linked lakes, often used for paleoenvironmental analysis, should be expected to reflect
isotopic complexities of the type shown here.
Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. 相似文献
3.
4.
Diatom assemblages preserved in sediment cores from closed-basin lakes can provide high-resolution records of past hydrologic and climatic conditions, including long-term patterns in the intensity, duration, and frequency of droughts. At Moon Lake, a closed-basin lake in eastern North Dakota, a comparison of diatom-inferred salinity and the precipitation-based Bhalme-Mooley Drought Index (BMDI) over the last 100 years was highly significant, suggesting that the diatom record contains a sensitive archive of past climatic conditions. A sub-decadal record of inferred salinity for the past 2300 years indicates that extreme droughts of greater intensity than those during the 1930s 'Dust Bowl' were more frequent prior to A.D. 1200. This high frequency of extreme droughts persisted for centuries and was most pronounced from A.D. 200–370, A.D. 700–850 and A.D. 1000–1200. A pronounced shift to generally wetter conditions with less severe droughts of shorter duration occured at A.D. 1200. This abrupt change coincided with the end of the 'Medieval Warm Period' (A.D. 1000–1200) and the onset of the 'Little Ice Age' (A.D. 1300–1850). 相似文献
5.
湖泊面积可反映区域气候变化和人类活动等信息。选取1989、1994、1999、2004、2009、2014年Landsat遥感影像数据,采用人工目视解译、ArcGIS空间分析等方法分析毛乌素沙地湖泊面积变化特征,并结合毛乌素周边气象站点气象数据、所在县区统计年鉴数据对湖泊面积变化的影响因素进行分析。结果表明:(1)毛乌素沙地湖泊近30年总体上处于萎缩状态,具体表现为1994年前湖泊面积增加,后持续减小,不同面积等级湖泊变化情况不同;从空间上看,30年间湖泊面积减小明显的湖泊主要在东北部地区,面积增大明显的湖泊主要在西南部地区,中部地区湖泊面积相对稳定;(2)气候变化和人类活动是近30年影响毛乌素沙地湖泊面积的主要因素。2000年前,湖泊面积主要受气温、降水的影响。特别是1989-1994年,湖泊面积变化量在空间上呈现显著的正相关关系;(3)2000年后,随着区域内人类活动的加剧,湖泊面积主要受人类活动的影响,在人类活动的干扰下,湖泊面积变化量在空间上未表现出显著的正相关关系。 相似文献
6.
内蒙古呼伦贝尔草原湖泊变化研究 总被引:1,自引:0,他引:1
内蒙古呼伦贝尔地区湖泊数量多,面积大,占内蒙古湖泊总面积的58%。近年来该地区湖泊趋于萎缩,但是已有研究主要关注大型湖泊,缺乏对该地区湖泊整体,尤其是小型湖泊(<1 km2)的研究。通过利用Landsat系列(TM、ETM+、OLI)卫星数据,参照该地区湖泊图集、湖泊名录以及Google Earth高清影像,分析了1986—2017年呼伦贝尔草原地区湖泊数量和面积变化;在此基础上结合气候和人类活动资料,讨论湖泊变化的影响因素。研究表明:近30 a呼伦贝尔地区湖泊显著萎缩,其中变化最为剧烈的是小型湖泊,新增5个,干涸19个,总面积减小超过30%。2000年前各类型湖泊面积均有增加,1998年降水量最大,湖泊面积相应达到峰值;2000—2010年湖泊面积呈萎缩趋势;2010年以后有所回升。将湖泊面积与气候条件(气温、降水量、潜在蒸散量)及人为活动因子(放牧强度、原煤产量、有效灌溉面积)进行相关分析发现,湖泊面积变化主要受人类活动的影响,气候变化的影响相对较小。 相似文献
7.
Predicted changes in future climate necessitate a better understanding of climate impacts on lake biota, and the role of within-lake
processes in modifying biotic response. Therefore we examined two climate-related variables (lake-water conductivity and GRIP
temperatures) and lake ontogeny (lake age), to determine their influence on lake autotrophic communities in two neighbouring
closed-basin lakes from West Greenland spanning the past 8,000 years. Using sedimentary pigments as proxies for lake autotrophic
communities, we used synchrony and variance partitioning analyses (VPA) to test three specific hypotheses (a) that lake primary
production would increase with lake age, (b) that climate would be the dominant process controlling autotrophic communities
in these pristine lakes and (c) that the response of autotrophs to conductivity and temperature would vary depending upon
the age of the lake. The results supported our first hypothesis, showing that lakes changed significantly with age, exhibiting
an increase and decline in production in the first millennium of their existence, followed by a steady increase in production
and increasingly frequent abrupt switches between mixed and meromictic states. The highly synchronous detrended response (r = 0.769) of lake autotrophs in the two study lakes, supported our hypothesis that climate was the dominant factor controlling
lake autotrophs. However, VPA revealed that our climate-related variables (temperature and conductivity) explained only small
amounts of variance alone (<12.9%) because covariance among them hindered efficient partitioning. In support of our third
hypothesis, autotrophs responded significantly to temperature and conductivity in interaction with lake age (>50% variance
explained) and with each other (>28% variance explained), such that autotrophic response changed as lakes aged. In spite of
this, lakes sometimes responded independently, as a result of differences in the relative proportion of benthic to pelagic
production and because of differences in lake morphometry. Together these results show that long-term control of lake autotrophs
by climate and lake age is modified on shorter timescales by non-linear responses related to within-lake processes, and by
the interaction of different climate variables with each other and with lake age. 相似文献
8.
利用多源遥感数据解译、野外考察、原位观测等方法,分析了巴丹吉林沙漠腹地湖泊群湖冰冻结-消融空间模式及其差异的主要影响因素。结果表明:该沙漠存在4种冻结-消融空间模式,湖冰自湖岸蔓延至湖心、冻结早的区域融化晚;湖冰自湖岸蔓延至湖心、冻结早的区域融化早;湖冰自湖泊一岸扩展至另一岸、冻结早的区域融化晚;湖冰自湖泊一岸扩展至另一岸、冻结早的区域融化早。大部分面积较小湖泊的冻结-消融空间模式为从湖岸冻结至湖心,冻结早的区域消融晚。不同冻结-消融空间模式之间的差异反映了泉水与地下水对湖泊的补给作用,同一盆地内部或同一沙山两侧孪生湖泊湖冰物候特征的差异主要受湖泊形态特征、湖泊溶解性固体总量(TDS)、局地气候条件的影响,有泉水或地下水出露、TDS越低、水位越浅、风力越小的区域冻结越早。泉水、地下水与湖水混合后使湖水TDS降低,更易于冻结,这是巴丹吉林沙漠大部分湖泊冰的最初生成形式,表明巴丹吉林沙漠湖冰物候在一定意义上是湖泊群接受区域深层地下水补给的直接反映。 相似文献
9.
以Landsat卫星1972~2013年间5个时期的遥感影像数据为基础,结合野外实际调查和室内解译分析,运用RS和GIS技术,提取影像中盐湖湖水边界信息,并绘制了5个时期盐湖面积变化的图谱。结合库木库勒盆地气象数据(年降水量、平均气温、相对湿度、平均风速)对盐湖面积变化进行响应分析,探究盐湖变化与气候之间的相关性,并讨论气候变化对库木库勒盆地内盐湖面积变化的影响机制,探讨不同气象因子对盆地内盐湖面积变化的作用。平均气温、降水量、相对湿度对盆地内盐湖的面积扩大均有促进作用,且平均气温的作用占主导性,这为库木库勒盆地盐湖的演化研究以及盐湖资源开发提供了相应参考和借鉴材料。 相似文献
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11.
近20年青海湖水量变化遥感分析 总被引:2,自引:0,他引:2
青藏高原湖泊水量的变化是揭示全球气候变化及其区域水循环响应的重要信息载体。区别于常用的水文学方法,本文利用MODIS遥感影像和LEGOS高度计多年连续数据,基于湖泊水位—面积关系,探讨了湖泊水量变化的遥感分析方法,并以青藏高原面积最大的青海湖为例,揭示青海湖近20年来(2001-2016)湖泊水量年内与年际变化特征。主要结论为:青海湖湖泊面积在2001-2016年间整体扩张了187.9 km2,变化速率为11.6 km2/a;水位在2001-2014年间上升了1.15 m,变化速率为0.10 m/a。青海湖水位—面积关系表现为二次函数关系(相关系数R2=0.83)。基于水位—面积关系,进一步估算分析了青海湖水量平衡的净收支及其年内和年际变化。近20年来,青海湖水量总体呈增加趋势,其变化率约为4.5
12.
巴丹吉林沙漠湖泊与地下水的补给来源及化学组成(英文) 总被引:1,自引:0,他引:1
Based on the analysis of ion chemical composition of lake water and shallow groundwater in the Badain Jaran Desert, this paper discussed the characteristics of ion chemical composition, spatial variation of lake water, and possible supply sources of lake water and groundwater in the desert areas. The results show that the pH, salinity, TDS and electrical conductivity of the lake water are greater than those of groundwater. The ion con-tents of water samples are dominated by Na+ and Cl?. Most of the higher salinity lakes are Na (K)-Cl-(SO4) type, and a few of low salinity lakes belong to the Na-(Mg)-(Ca)-Cl-(SO4)-(HCO3) type. Most of the groundwater is Na-(Ca)-(Mg)-Cl-(SO4)-(HCO3) type, attributed to subsaline lake, and only a few present the Na-Cl-SO4 type, flowing under saline lake. The pH, salinity, TDS and electrical conductivity in the southeastern lakes are relatively low, and there are slightly alkaline lakes. The pH, salinity, TDS and electrical conductivity in the northern lakes are much greater than those of the southeastern lakes, and the northern lakes are moderately alkaline and saline ones. In the southeastern part of the Badain Jaran Desert, the ion chemical characteristics of the lake water from south to north show a changing trend of sub-saline →saline→hypersaline. The changing trend of chemical compositions of ions in recent 9 years indicates that most of the ion contents have a shade of reduction in Boritaolegai, Badain, Nuoertu and Huhejilin lakes, which state clearly that the amount of fresh water supply is increasing in the 9-year period. The ion chemical composition of the lake water reveals that the flow direction of lake water is from southeast to northwest in the Badain Jaran Desert. The ion chemical composition, moisture content of sand layer water level height and hierarchical cluster analysis of the lake water and groundwater demonstrate that the lake water is mainly supplied by local rainfall and infiltration of precipitation in Yabulai Mountains and Heishantou Mountain, and the supply from the Qilian Mountains is almost impossible. 相似文献
13.
湖泊是陆地水资源的重要组成部分,也是局地气候和全球环境变化的敏感指示器之一。湖泊面积增加和水位的变化直接反映了流域内水量平衡变化过程,对区域和全球的气候变化的反映较为敏感。利用线性趋势法对青海湖流域长时间序列气象、水文资料以及流域水热条件和植被生长状况进行分析研究,利用皮尔逊相关系数法计算了各因素与湖水位的相关关系,旨在定量评估区域气象、水文、植被等要素的变化对和湖泊水位变化过程的贡献,开展细致的青海湖水位变化特征的影响因子探讨与分析。结果表明:该流域气候呈现显著的暖湿化趋势,其中流域年降水量总体上呈现弱的增加态势,气候倾向率为10.8 mm·(10 a)-1;流域年平均气温呈显著的升高趋势(P <0.01)。流域年可能蒸散率和年实际蒸散波动较大,年实际蒸散虽有波动但增加趋势非常明显(P <0.01)。流域净第一性生产力(P)平均值为2.86 t DM·hm-2·a-1,呈现显著的增加趋势(P <0.01)。从1961年开始湖水位呈现逐年波动下降的趋势,到2004年水位最低(P<0.01);2004—2015年的近10 a连续上升,上升速率达14.4 m·(10 a)-1(P <0.01)。流域气温升高、降水量增加,流域气候呈显著的暖湿化特征,入湖河流径流量也呈现出弱的增加态势;气候暖湿化特征导致流域生物温度增加,植被生长状况得到改善,[WTBX]NPP[WTBZ]显著增加。年降水量增多,河流径流量增大,湖水位抬升;前一年的降水量、≥0 ℃积温、温度、径流量、NPP和蒸发量对湖水位的影响更大;NDVI和NPP的增加反映流域植被生长状况得到好转,从而增加了流域植被水土保持和水源涵养能力,对湖水位产生间接的影响。降水量、≥0 ℃积温、温度、径流量和NPP对青海湖水位起到正反馈效应,而蒸发量对湖水位主要起负反馈效应,年降水量和年径流量是湖水位变化的最直接的影响因子。 相似文献
14.
湖泊岸线形态是描述和定量表达湖泊空间分布特征的重要维度。近年来,受气候暖湿化影响,青藏高原内流区湖泊总体呈现快速扩张趋势,湖泊的动态变化不仅体现在面积、水位、水量等水文参数上,还引起湖泊形态的显著变化。基于多期湖泊分布数据,结合分形和景观生态学理论,构建了湖泊岸线形态特征量化的指标体系,对1990年以来,青藏高原内流区湖泊岸线形态的时空变化特征及其影响因素进行定量分析。结果表明:① 近三十年来青藏高原内流区湖泊的分形维数和岸线发育系数总体呈上升趋势,湖泊的近圆率在此期间呈下降趋势,湖泊长宽比指数则无明显变化。② 青藏高原内流区湖泊岸线形态的总体演变特征受到地质构造的控制,体现出一定空间自相关性,断陷湖区的湖泊岸线形态及其变化要明显复杂于坳陷湖区。区域湖泊岸线的变化幅度大致从东北向西南递减,变化幅度在可可西里地区、羌塘高原中部以及羌塘高原东南部3个区域存在空间自相关性。③ 湖泊岸线形态的变化受岸线周边的地形影响,湖滨地形落差较大的区域,湖泊岸线相对稳定,变化速度较慢。岸线指数的变化量与岸线周边1 km缓冲区内的平均高差存在幂函数关系。④ 该区域湖泊岸线形态的变化和湖泊面积的变化幅度也存在一定相关性,当湖泊处于扩张阶段时,湖泊的分形维数和岸线发育系数总体呈现增加趋势,反之减少。本研究揭示了气候暖湿化背景下青藏高原内流区湖泊岸线形态的变化格局与影响特征,讨论了湖泊岸线形态及其变化格局与湖区的地质构造,气候与水文等多个要素间的关系,丰富了湖泊动态变化研究的视角与方法,为深入理解青藏高原湖泊对气候变化的响应特征,监测湖泊变化对湖盆地貌、水系连通度以及湖滨带生态环境等影响提供了科学参考。 相似文献
15.
The influence of Asian summer monsoon variability on the water balance of a Tibetan lake 总被引:2,自引:0,他引:2
Carrie Morrill 《Journal of Paleolimnology》2004,32(3):273-286
Past water-balance changes in Tibetan lakes are generally attributed to changes in the strength of the summer monsoon. However, the water balance of a lake reflects many different water fluxes, which are controlled by many climatic and hydrologic processes. In this research, weather data and evaporation models are used to determine the climatic cause of a recent water-balance change in Ahung Co, a lake in central Tibet. Between 1995 and 2001, lake level rose at least 20 cm and the lake began to overflow. Results indicate that an increase in summer monsoon precipitation over the lake and drainage basin is responsible for the rise in lake level. Stronger monsoon conditions between 1995 and 2001 also led to decreased lake evaporation and basin evapotranspiration due to increased clouds and humidity. This contributed to the rise in lake level, but to a much smaller extent than the increase in monsoon precipitation. Lake evaporation during the spring and fall was also reduced between 1995 and 2001 due to longer lasting ice cover. Variations in ice cover play a small role in the overall water balance of Ahung Co, however, because the lake area is small compared to the drainage basin area. If these results hold true for the past, water-balance fluctuations inferred from the geochemistry of sediments from Ahung Co provide a record of variations in monsoon precipitation during the Holocene. 相似文献
16.
Miriam Dühnforth Andreas G. N. Bergner Martin H. Trauth 《Journal of Paleolimnology》2006,36(3):281-294
The Nakuru-Elmenteita basin in the Central Kenya Rift, contains two shallow, alkaline lakes, Lake Nakuru (1770 m above sea level) and Lake Elmenteita (1786 m). Ancient shorelines and lake sediments at 1940 m suggest that these two lakes formed a single large and deep lake as a result of a wetter climate during the early Holocene. Here, we used a hydrological model to compare the precipitation–evaporation balance during the early Holocene to today. Assuming that the Nakuru-Elmenteita basin was hydrologically closed, as it is today, the most likely climate scenario includes a 45% increase in mean-annual precipitation, a 0.5°C decrease in air temperature, and an increase of 9% in cloud coverage from the modern values. Compared to the modeling results from other East African lake basins, this dramatic increase in precipitation seems to be unrealistic. Therefore, we propose a significant flow of water from the early Holocene Lake Naivasha in the south towards the Nakuru-Elmenteita basin to compensate the extremely negative hydrological budget of this basin. Since we did not find any field evidence for a surface connection, as often proposed during the last 70 years, the hydrological deficit of the Nakuru-Elmenteita basin could have also been compensated by a subsurface water exchange. 相似文献
17.
近30年来西藏那曲地区湖泊变化对气候波动的响应 总被引:33,自引:4,他引:29
根据1975年地形图、20世纪80年代至2005年的TM、CBERS卫星遥感资料和近45年的气温、降水量、蒸发量、最大积雪深度和最大冻土深度等气候资料分析得出,西藏那曲地区东南部的巴木错、蓬错、东错、乃日平错等四个湖泊的水位面积在近30年来呈较显著的扩大趋势,2005年与1975年相比,分别增加了48.2 km2、38.2km2、19.8 km2 (比2004年)、26.0 km2,增长幅度分别为25.6%、28.2%、16.2%、37.6%。其主要原因与该地区近年来气温的上升、降水量的增加和蒸发量的减少、冻土退化等暖湿化的气候变化有很大关系。 相似文献
18.
Kelan River is a branch of the Ertix River, originating in the Altay Mountains in Xinjiang, northwestern China. The upper streams of the Kelan River are located on the southern slope of the Altay Mountains; they arise from small glacial lakes at an elevation of more than 2,500 m. The total water-collection area of the studied basin, from 988 to 3,480 m, is about 1,655 km2. Almost 95 percent of the basin area is covered with snow in winter. The westerly air masses deplete nearly all the moisture that comes in the form of snow during the winter months in the upper and middle reaches of the basin. That annual flow from the basin is about 382 mm, about 45 percent of which is contributed by snowmelt. The mean annual precipitation in the basin is about 620 mm, which is primarily concentrated in the upper and middle basin. The Kelan River system could be vulnerable to climate change because of substantial contribution from snowmelt runoff. The hydrological system could be altered significantly because of a warming of the climate. The impact of climate change on the hydrological cycle and events would pose an additional threat to the Altay region. The Kelan River, a typical snow-dominated watershed, has more area at higher elevations and accumulates snow during the winter. The peak flow occurs as a result of snow-melting during the late spring or early summer. Stream flow varies strongly throughout the year because of seasonal cycles of precipitation, snowpack, temperature, and groundwater. Changes in the temperature and precipitation affect the timing and volume of stream-flow. The stream-flow consists of contributions from meltwater of snow and ice and from runoff of rainfall. Therefore, it has low flow in winter, high flow during the spring and early summer as the snowpack melts, and less flows during the late summer. Because of the warming of the current climate change, hydrology processes of the Kelan River have undergone marked changes, as evidenced by the shift of the maximum flood peak discharge from May to June 相似文献
19.
青藏高原湖泊变化遥感监测及其对气候变化的响应研究进展 总被引:1,自引:1,他引:0
青藏高原位于中国西南部、亚洲中部,平均海拔高程大于4000 m,面积约300万km2,是“世界屋脊”,与周边地区一起常被称为地球的“第三极”。青藏高原分布着约1200个面积大于1 km2的湖泊,占中国湖泊数量与面积的一半;同时也是黄河、长江、恒河、印度河等大河的源头,被称为“亚洲水塔”。近几十年来,在全球变暖的背景下,青藏高原升温更加突出,其能量与水循环发生了显著变化,气候趋于暖湿化,冰川加速消融,湖面水位上升。湖泊是气候变化的重要指标,青藏高原湖泊分布密集、人为活动影响较小,多源遥感数据的广泛应用,为监测高原湖泊变化提供了难得的契机。本文依托国家自然科学基金青年项目“基于多源遥感的青藏高原内流区湖泊水量变化及水体相态转换研究(2000-2009年)”,主要研究进展为:初步查明了西藏高原的湖泊数量、面积及水位变化与时空格局,以及湖泊水量变化与水量平衡;探讨了湖泊变化对气候变化的响应。目前对青藏高原湖泊的变化及驱动因素虽有一些认识,但其定量的水量平衡及驱动机制还有待于进一步研究。这对了解世界第三极、一带一路国家和地区水资源状况与变化、生态文明和生态安全屏障建设具有重要的意义,同时也可为第三极国家公园的建立提供重要的科学基础。 相似文献
20.
新疆沙尘暴源区的气候与荒漠环境变化 总被引:28,自引:11,他引:17
根据新疆地区50年来的气候变化以及人类活动的影响,阐述了新疆沙尘暴源区气候与荒漠环境变化。结果表明,新疆地区的气候由暖干向暖湿发展。自20世纪70年代中期以来,暖湿过程非常明显,特别是新疆南疆与北疆的气候变化特点和高山与盆地的气候变化差异以及湖泊水域面积的变化,都明显地反映了干旱区域气候变化的敏感性,并且也反映了新疆区域气候与中国中、东部气候变化的差异性。由于气候的波动变化和人类活动的干扰,使荒漠环境也在不同区域受到不同程度影响,尤其是干旱地区的降水、大气湿润程度和下垫面状况都直接影响着沙尘暴的发生和发展。20世纪80年代后期以来,温度的突变是造成环境恶化、灾害增多的主要原因之一,同时也反映出干旱内陆区是气候变化过程中的敏感反应区。 相似文献