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1.
《资源与生态学报(英文版)》2017,(1)
位于喜马拉雅中部的柯西河流域(Koshi River Basin,简称KRB),是恒河支流也是南亚极为重要的跨境流域。流域内海拔落差巨大、生境复杂、生态系统类型完整、土地覆被类型多样且区域差异明显,是全球气候变化的敏感区之一。本研究基于Landsat TM、野外考察及植被图等多源数据,运用3S技术,编制了高精度的柯西河流域土地覆被数据,分析了流域土地覆被现状特征。研究表明:(1)2010年KRB土地覆被从流域源头至下游由雪被和水体(冰川)、裸地、稀疏植被、草地、湿地、灌丛、森林、农田、水体(河流和湖泊)、建设用地等9类组成。其中,以草地、森林、裸地和农田为主,分别占流域面积的25.83%、21.19%、19.31%和15.09%。而对气候变化敏感的冰川面积仅占5.72%。(2)KRB南、北坡土地覆被类型组成与结构迥异。北坡以草地、裸地和冰川分布为主,南坡以森林、农田和裸地为主;草地在北坡的分布面积远高于南坡,二者比例是6.67:1,而森林面积的97.13%分布在南坡,这些森林大多分布在河谷中部和南部平原地区,且与农田交错分布。(3)与环境相适应,流域主要覆被类型的垂直分布也具有明显的地带性特征。土地覆被由低到高,依次为农田、森林、灌丛和农田混合型、草地、稀疏植被、裸地和水体(冰川)的分布。研究结果为土地利用和覆被变化研究、为高山地区尤其是跨境流域的生态系统保护与管理、土地资源利用和可持续发展提供科学依据。 相似文献
2.
秦岭陕西段南北坡植被对干湿变化响应敏感性及空间差异 总被引:1,自引:0,他引:1
秦岭位于暖温带与亚热带交界处,也是中国南北地理分界线,秦岭南北坡植被对干湿变化响应敏感性,可以折射出暖温带、亚热带地区主要植被类型对干湿变化的响应规律和机制特征,对深入理解不同气候带植被变化规律具有重要意义。本文利用秦岭山地32个气象站点的气象数据和MODIS NDVI时间序列数据集,探讨了2000—2018年秦岭南北坡NDVI和SPEI时空变化特征,揭示了南北坡植被对干湿变化响应敏感性及其空间差异。结果表明:① 2000—2018年秦岭植被覆盖情况整体显著改善,但秦岭南坡NDVI上升幅度和面积占比均高于北坡,南坡植被比北坡改善情况好。秦岭湿润化趋势不显著,但秦岭北坡湿润化速率和面积占比均大于南坡。② 秦岭北坡植被比南坡植被更易受干湿变化影响,秦岭北坡植被对3—6月总体干湿变化最为敏感,南坡植被对3—5月(春季)干湿变化最为敏感。秦岭南北坡植被主要受3~7个月尺度干湿变化影响,对11~12个月尺度的干湿变化响应较弱。③ 秦岭有90.34%的区域NDVI与SPEI呈正相关,大部分地区春季湿润化能促进全年植被生长;随海拔上升,植被对干湿变化响应敏感性先上升再下降,海拔800~1200 m是植被响应最敏感的海拔段,海拔1200~3000 m随海拔上升植被响应敏感性下降;南北坡草丛均是对干湿变化响应最为敏感的植被类型,但秦岭北坡多数植被类型对干湿变化响应比南坡敏感。 相似文献
3.
秦巴山地垂直带谱结构的空间分异与暖温带—亚热带界线问题 总被引:1,自引:2,他引:1
秦巴山地垂直带谱结构的空间分异对于揭示秦巴山地地域结构复杂性和过渡性、探索中国复杂的生态地理格局具有重要的意义。本文从文献中搜集了秦巴山地33个山地垂直带谱,建立了秦巴山地数字垂直带谱体系,从纬向、经向和坡向3个维度分析了山地垂直带谱的结构、特征、数量、高度以及分布模式。结果表明:① 纬向上从南向北基带由亚热带常绿阔叶林带逐渐转变为暖温带落叶阔叶林带;垂直带结构由复杂逐渐变得简单;优势带由山地针阔混交林和山地常绿落叶阔叶混交林转变为山地落叶阔叶林带;② 经向上山地垂直带结构呈现复杂—简单—复杂的特征;常绿落叶阔叶混交林带和山地落叶阔叶林带的海拔呈现了二次曲线分布模式;山地针阔混交林带的海拔则呈现显著的线性降低趋势;③ 坡向方面,秦岭北坡和南坡基带均为暖温带落叶阔叶林带,但南坡含有常绿成分;大巴山北坡为亚热带常绿落叶阔叶混交林带,大巴山南坡为亚热带常绿阔叶林带;秦岭和大巴山北坡优势带类似,均为山地针阔混交林带或山地落叶阔叶林带,但大巴山南坡具有独特的山地常绿落叶阔叶混交林优势带,这表明了大巴山比秦岭更适合作为暖温带和北亚热带的分界线,但是未来还需使用土壤和气候指标进行系统的分析。 相似文献
4.
秦岭太白山气温直减率时空差异性研究 总被引:12,自引:3,他引:9
在评估山地生态系统对气候变化响应的过程中,作为气温要素的重要输入参数,气温直减率(γ)的精确性直接影响到相关科研工作的真实性和可靠性。本文基于秦岭主峰太白山(3771.2 m)11个分布于南北坡和不同海拔的标准气象站点2013-2015年连续3年实测日均温资料和25 m×25 m空间分辨率的DEM数据,研究了太白山气温直减率在不同时间尺度上的变化规律及不同坡向上的空间分布特征。结果表明:① 2013-2015年太白山年均γ北坡均大于南坡,北坡为0.513 ℃/100m,南坡为0.499 ℃/100m;北坡年均γ随海拔变化表现出一定的差异性,而南坡相对稳定。② 年内γ在不同时间尺度上均存在明显差异,且南北坡变化趋势不一致。在季尺度上,γ最大值北坡为夏季,为0.619 ℃/100m,而南坡最大出现在春季,为0.546 ℃/100m,最小值均为冬季,南北坡分别为0.449 ℃/100m和0.390 ℃/100m;春季和夏季,北坡γ均大于南坡,而冬季相反,北坡小于南坡,秋季几乎无差异。在月尺度上,气温相对高的月份γ亦较高,北坡γ变化幅度大于南坡;年始和年末(11-12月、1-2月)北坡γ小于南坡,而5-9月北坡大于南坡,且南北坡γ相差较大。③ 经数据可信度分析,所获得的γ可较为客观地反映太白山气温随海拔变化的规律性,将为山地气温空间分布规律及其生态系统响应等定量研究提供理论基础。 相似文献
5.
南迦巴瓦峰与托木尔峰山地垂直自然带的比较 总被引:2,自引:0,他引:2
南迦巴瓦峰地处喜马拉雅山脉东端雅鲁藏布江大拐弯的内侧,托木尔峰地处天山山脉的西端,二者独特的自然地理特征及其高大的山体为山地垂直自然带谱的形成和发展提从了十分有利的自然环境,发育了相当完整的山地垂直系列。比较二者的垂直带谱,可以发现无论在垂直带谱的形成条件,基带,性质和结构类型,还是景观特征,垂直分异影响因素及南北坡差异程度等方面,都存在着较大的差异。南峰垂直带谱为以森林-草原-荒漠土壤系列为特征的季风性湿润,法湿润带谱系统,垂直分异的主导因素为温度;托峰垂直带谱为以荒漠--草原-荒漠土壤系列为特征的大陆性干旱带谱系统,垂直分异的主导因素为湿度。不同的垂直自然带特征决定了不同的资源开发利用和保护措施。 相似文献
6.
岷江上游雨季南北坡小气候特征比较 总被引:9,自引:5,他引:9
利用岷江上游茂县大沟不同坡向的小气候观测资料,探讨了该地区地雨季的太阳辐射、气温、地表温、水汽压、相对湿度、风速等小气候要素的南北坡特征及其与谷底的差异。通过比较分析得出:在雨季南坡的太阳辐射量大于北坡和谷底;南北坡气温、水汽压、相对湿度在昼间有一定差异;北坡气温略高于南坡;气温垂直递减率南坡(O.71℃/100m)大于北坡(O.61℃/100m)。水汽压为北坡<南坡<谷底;而相对湿度为谷底<北坡<南坡,北坡和谷底的太阳辐射、气温、地表温、水汽压最大值比南坡早出现1h。南北坡风速均大于谷底,而南坡风速又大于北坡。由此可见,岷江上游地区即使在雨季,山地对局地气候仍有一定影响。 相似文献
7.
南水北调中线水源区土地利用/土地覆被的空间格局 总被引:25,自引:1,他引:24
土地利用/土地覆被 (简称LULC) 变化对流域水资源动态具有深刻的影响。这对于我国大规模跨流域的南水北调工程规划尤为重要。本文制定了该工程中线水源区约95 000 km2 面积的LULC分类系统,利用2000年前后的TM影像完成LULC分布现状图,并结合DEM分析了其土地利用/土地覆被的空间格局特征。结果表明:① 研究区域森林覆盖率为50.97%,灌丛25.58%;农田约占15%,其中旱地与水田的比例约10:3;石砾裸地等强烈退化类型合占5.66%;水域约占1%。② 区内秦岭南坡、汉-丹平原丘陵、巴山北坡三部分的LULC结构存在显著差异,强度土地利用类型和退化土地类型主要分布在汉-丹平原丘陵地区;秦岭南坡耕地的水分条件较巴山北坡好,但局部土地退化现象也更严重。③ 地形对LULC具有明显影响。海拔高度控制着自然植被的垂直分异和各种土地利用类型及利用强度的分布;各土地覆被类型的分布显示了坡度对土地开发强度的限制作用;坡向对局部LULC格局的影响并不显著,但在区域尺度上可能对秦岭南坡与巴山北坡的LULC结构差异具有贡献。南水北调中线工程水源区当前的LULC结构和空间格局显示,总体上植被状况良好,高强度的土地利用类型主要集中于海拔1000m以下的平缓地区,而退化土地类型也主要存在于这一区域,是流域水质保护和环境治理的关键区域。 相似文献
8.
横断山区垂直带谱的分布模式与坡向效应 总被引:5,自引:1,他引:4
根据收集到的横断山区山地垂直带谱数据,对山地垂直带的坡向效应和空间分布规律进行了分析和研究.结果表明:1)主要的垂直带和垂直带界线如林线、暗针叶林带、雪线等的纬度和经度地带性分布规律明显并且分布模式都相似,纬向上呈开口向下的二次曲线分布模式,经向上呈开口向上的二次曲线分布模式,两者共同形成"双曲抛物面"分布模式,充分反映了横断山区的环境与生态的复杂性和独特性,也进一步丰富和发展了山地垂直带谱的二次曲线假说; 2)横断山区山地垂直带谱表现出明显的基于水分驱动的坡向效应,主要表现为同一山体的东、西坡往往具有不同的基带和带谱结构,相同类型的带谱出现的海拔和分布范围不同,迎风坡表现出较为湿润的类型和带谱结构,而背风坡则表现出更为干旱的类型和组成结构;横断山区的坡向效应主要是由于山体对当地盛行季风的影响,造成迎风坡和背风坡水热条件相差很大,从而发育不同的山地垂直带谱类型.从横断山区山地垂直带谱的空间分布规律来看, 28°~29°N、98°~101°E范围内,即大致在澜沧江以东-雅砻江以西,山地垂直带谱普遍表现出干热的特点,为横断山区干热气候的核心地带.但如何定量分析山地的坡向效应尚有待于进一步的研究和讨论.此外、数据质量和数据误差也对分析的结果,尤其是空间分布模式的数学模拟结果产生一定的影响,在以后的研究中尚需进一步完善. 相似文献
9.
秦岭中部山地落叶阔叶林超级垂直带的发现与意义 总被引:1,自引:1,他引:0
山地垂直带谱是气候和植被水平地带变化和更替的缩影,垂直带的带幅、带间过渡方式、带内结构和垂直带组合方式都表现出高度的异质性和复杂性。本文发现在中国南北过渡带中部太白山发育了世界上最宽的山地垂直带——山地落叶阔叶林垂直带。该垂直带从基带到典型垂直带再到先锋性垂直带皆为山地落叶阔叶林,3种本来可以独立存在的垂直带,连续分布形成了包含3个栎林亚带、2个桦林亚带的“三层五亚带”超级垂直带,远远超过正常情况下山地垂直带1000 m的阈值,且其上限达到了海拔2800 m。它的形成与秦岭所处的过渡性地理位置、秦岭中部垂直带谱的完整性、丰富的落叶木本植物种群及其形成的强大群落竞争优势等因素紧密相关。超级垂直带的发现有多方面的意义:它是中国南北过渡带又一重要的标志性自然地理特征;它表明山地垂直带在特殊的山地环境中可以具有非常复杂的内部结构和宽大带幅,这扩展了我们对山地垂直带谱结构及机理认识的广度,对于创建山地垂直带谱结构理论具有十分重要的意义;超级垂直带的发现,也说明中国南北过渡带还有很多科学内容有待我们去探索和发现,希望本文能起到抛砖引玉的作用,引起学界对超级垂直带形成的气候和生物多样性因素、地理过渡带的结构和生态效应等重大问题进行深入研究。 相似文献
10.
从秦岭蕨类植物区系地理成分论秦岭山地生态分界线的划分 总被引:6,自引:0,他引:6
依据2007~2008年野外实地调查以及相关文献资料,运用植物区系地理学和数量生态学方法,分析了秦岭蕨类植物区系的物种组成和地理分布特征,划分了秦岭蕨类植物的垂直带谱,并以此为基础探讨了秦岭山地生态分界线的划分,得出以下主要结论:(1)秦岭共有蕨类植物36科85属311种,优势科为鳞毛蕨科、蹄盖蕨科和水龙骨科,优势属为鳞毛蕨属和耳蕨属;在科属水平上,以热带成分占优势;而种的水平则以温带成分占绝对优势。(2)根据秦岭蕨类植物南北坡垂直带谱的对比分析,南坡海拔1000m左右应该是一条重要的生态分界线。(3)南坡1000m以下蕨类植物区系组成更接近亚热带区系,而其他地带则与温带蕨类植物区系更为接近,DCA排序很好地证明了此结果。综合来看,将南坡海拔1000m作为秦岭山地亚热带与暖温带的生态分界线较为科学。 相似文献
11.
Vertical differentiation of land cover in the central Himalayas 总被引:1,自引:0,他引:1
Characterized by obvious altitudinal variation, habitat complexity, and diversity in land cover, the Mt. Qomolangma region within the central Himalayas is one of the most sensitive areas to climate change in the world. At the same time, because the Mt. Qomolangma region possesses the most complete natural vertical spectrum in the world, it is also an ideal place to study the vertical structure of alpine land cover. In this study, land cover data for 2010 along with digital elevation model data were used to define three methods for dividing the northern and southern slopes in the Mt. Qomolangma region, i.e., the ridgeline method, the sample transect method, and the sector method. The altitudinal distributions of different land cover types were then investigated for both the northern and southern slopes of the Mt. Qomolangma region by using the above three division methods along with Arc GIS and MATLAB tools. The results indicate that the land cover in the study region was characterized by obviously vertical zonation with the south-six and north-four pattern of vertical spectrum that reflected both the natural vertical structure of vegetation and the effects of human activities. From low to high elevation, the main land cover types were forests, grasslands, sparse vegetation, bare land, and glacier/snow cover. The compositions and distributions of land cover types differed significantly between the northern and southern slopes; the southern slope exhibited more complex land cover distributions with wider elevation ranges than the northern slope. The area proportion of each land cover type also varied with elevation. Accordingly, the vertical distribution patterns of different land cover types on the southern and northern slopes could be divided into four categories, with glaciers/snow cover, sparse vegetation, and grasslands conforming to unimodal distributions. The distribution of bare land followed a unimodal pattern on the southern slope but a bimodal pattern on the northern slope. Finally, the use of different slope division methods produced similar vertical belt structures on the southern slope but different ones on the northern slope. Among the three division methods, the sector method was better to reflect the natural distribution pattern of land cover. 相似文献
12.
WU Xue PAUDEL Basanta ZHANG Yili LIU Linshan WANG Zhaofeng XIE Fangdi GAO Jungang SUN Xiaomin 《地理学报(英文版)》2021,31(10):1419-1436
The study of mountain vertical natural belts is an important component in the study of regional differentiation.These areas are especially sensitive to climate change and have indicative function,which is the core of three-dimensional zonality research.Thus,based on high precision land cover and digital elevation model (DEM) data,and supported by MATLAB and ArcGIS analyses,this paper aimed to study the present situation and changes of the land cover vertical belts between 1990 and 2015 on the northern and southern slopes of the Koshi River Basin (KRB).Results showed that the vertical belts on both slopes were markedly dif-ferent from one another.The vertical belts on the southern slope were mainly dominated by cropland,forest,bare land,and glacier and snow cover.In contrast,grassland,bare land,sparse vegetation,glacier and snow cover dominated the northern slope.Study found that the main vertical belts across the KRB within this region have not changed substantially over the past 25 years.In contrast,on the southern slope,the upper limits of cropland and bare land have moved to higher elevation,while the lower limits of forest and glacier and snow cover have moved to higher elevation.The upper limit of alpine grassland on the northern slope retreated and moved to higher elevation,while the lower limits of glacier and snow cover and vegetation moved northward to higher elevations.Changes in the vertical belt were influenced by climate change and human activities over time.Cropland was mainly controlled by human activities and climate warming,and the reduced precipitation also led to the abandonment of cropland,at least to a certain extent.Changes in grassland and forest ecosystems were predominantly influenced by both human activities and climate change.At the same time,glacier and snow cover far away from human activities was also mainly influenced by climate warming. 相似文献
13.
Glaciers are one of the most important land covers in alpine regions and especially sensitive to global climate change. Remote sensing has proved to be the best method of investigating the extent of glacial variations in remote mountainous areas. Using Landsat thematic mapping (TM) and multi-spectral-scanner (MSS) images from Mt. Qomolangma (Everest) National Nature Preserve (QNNP), central high Himalayas for 1976, 1988 and 2006, we derived glacial extent for these three periods. A combination of object-oriented image interpretation methods, expert knowledge rules and field surveys were employed. Results showed that (1) the glacial area in 2006 was 2710.17 ± 0.011 km2 (about 7.41% of the whole study area), and located mainly to the south and between 4700 m to 6800 m above sea level; (2) from 1976 to 2006, glaciers reduced by 501.91 ± 0.035 km2 and glacial lakes expanded by 36.88 ± 0.035 km2; the rate of glacier retreat was higher in sub-basins on the southern slopes (16.79%) of the Himalayas than on the northern slopes (14.40%); most glaciers retreated, and mainly occurred at an elevation of 4700–6400 m, and the estimated upper limit of the retreat zone is between 6600 m and 6700 m; (3) increase in temperature and decrease in precipitation over the study period are the key factors driving retreat. 相似文献
14.
Glacial change in the vicinity of Mt. Qomolangma (Everest), central high Himalayas since 1976 总被引:4,自引:0,他引:4
Glaciers are one of the most important land covers in alpine regions and especially sensitive to global climate change. Remote
sensing has proved to be the best method of investigating the extent of glacial variations in remote mountainous areas. Using
Landsat thematic mapping (TM) and multi-spectral-scanner (MSS) images from Mt. Qomolangma (Everest) National Nature Preserve
(QNNP), central high Himalayas for 1976, 1988 and 2006, we derived glacial extent for these three periods. A combination of
object-oriented image interpretation methods, expert knowledge rules and field surveys were employed. Results showed that
(1) the glacial area in 2006 was 2710.17 ± 0.011 km2 (about 7.41% of the whole study area), and located mainly to the south and between 4700 m to 6800 m above sea level; (2)
from 1976 to 2006, glaciers reduced by 501.91 ± 0.035 km2 and glacial lakes expanded by 36.88 ± 0.035 km2; the rate of glacier retreat was higher in sub-basins on the southern slopes (16.79%) of the Himalayas than on the northern
slopes (14.40%); most glaciers retreated, and mainly occurred at an elevation of 4700–6400 m, and the estimated upper limit
of the retreat zone is between 6600 m and 6700 m; (3) increase in temperature and decrease in precipitation over the study
period are the key factors driving retreat. 相似文献
15.
Climate change on the southern slope of Mt. Qomolangma (Everest) Region in Nepal since 1971 总被引:1,自引:0,他引:1
Based on monthly mean, maximum, and minimum air temperature and monthly mean precipitation data from 10 meteorological stations on the southern slope of the Mt. Qomolangma region in Nepal between 1971 and 2009, the spatial and temporal characteristics of climatic change in this region were analyzed using climatic linear trend, Sen's Slope Estimates and Mann-Kendall Test analysis methods. This paper focuses only on the southern slope and attempts to compare the results with those from the northern slope to clarify the characteristics and trends of climatic change in the Mt. Qomolangma region. The results showed that: (1) between 1971 and 2009, the annual mean temperature in the study area was 20.0℃, the rising rate of annual mean temperature was 0.25℃/10a, and the temperature increases were highly influenced by the maximum temperature in this region. On the other hand, the temperature increases on the northern slope of Mt. Qomolangma region were highly influenced by the minimum temperature. In 1974 and 1992, the temperature rose noticeably in February and September in the southern region when the increment passed 0.9℃. (2) Precipitation had an asymmetric distribution; between 1971 and 2009, the annual precipitation was 1729.01 mm. In this region, precipitation showed an increasing trend of 4.27 mm/a, but this was not statistically significant. In addition, the increase in rainfall was mainly concentrated in the period from April to October, including the entire monsoon period (from June to September) when precipitation accounts for about 78.9% of the annual total. (3) The influence of altitude on climate warming was not clear in the southern region, whereas the trend of climate warming was obvious on the northern slope of Mt. Qomolangma. The annual mean precipitation in the southern region was much higher than that of the northern slope of the Mt. Qomolangma region. This shows the barrier effect of the Himalayas as a whole and Mt. Qomolangma in particular. 相似文献
16.
The Koshi River Basin is in the middle of the Himalayas, a tributary of the Ganges River and a very important cross-border watershed. Across the basin there are large changes in altitude, habitat complexity, ecosystem integrity, land cover diversity and regional difference and this area is sensitive to global climate change. Based on Landsat TM images, vegetation mapping, field investigations and 3S technology, we compiled high-precision land cover data for the Koshi River Basin and analyzed current land cover characteristics. We found that from source to downstream, land cover in the Koshi River Basin in 2010 was composed of water body (glacier), bare land, sparse vegetation, grassland, wetland, shrubland, forest, cropland, water body (river or lake) and built-up areas. Among them, grassland, forest, bare land and cropland are the main types, accounting for 25.83%, 21.19%, 19.31% and 15.09% of the basin’s area respectively. The composition and structure of the Koshi River Basin land cover types are different between southern and northern slopes. The north slope is dominated by grassland, bare land and glacier; forest, bare land and glacier are mainly found on northern slopes. Northern slopes contain nearly seven times more grassland than southern slopes; while 97.13% of forest is located on southern slopes. Grassland area on northern slope is 6.67 times than on southern slope. The vertical distribution of major land cover types has obvious zonal characteristics. Land cover types from low to high altitudes are cropland, forest, Shrubland and mixed cropland, grassland, sparse vegetation, bare land and water bodies. These results provide a scientific basis for the study of land use and cover change in a critical region and will inform ecosystem protection, sustainability and management in this and other alpine transboundary basins. 相似文献
17.
Snow Accumulation on a Small High‐Arctic Glacier Svenbreen: Variability and Topographic Controls 
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下载免费PDF全文 Jakub Małecki 《Geografiska Annaler: Series A, Physical Geography》2015,97(4):809-817
One of the main controls on the net mass change of land‐terminating Arctic glaciers is the magnitude and distribution of snow accumulation. In Dickson Land, region of Svalbard with the greatest distance to the sea, the issue has not been receiving much scientific attention for decades. In this paper, new snow accumulation data are presented from Svenbreen in Dickson Land from end‐of‐winter surveys. The measured winter balance was 0.42 ± 0.15 m w.e. in 2010, 0.50 ± 0.10 m w.e. in 2011 and 0.62 ± 0.10 cm w.e. in 2012. Snow depth and water equivalent have been analysed in the background of altitude, slope and aspect extracted from the digital elevation model of the glacier. On steep northern slopes (>15°) accumulation was the highest, whereas it was decreased on southern slopes with moderate inclination (9–12°). Elevation, which on many glaciers proved to be highly correlated with snow depth, explained only 17–34% of snow depth variability due to complex interplay between local climate and geometry of a small valley. 相似文献
18.
珠穆朗玛峰北坡东绒布冰川成冰作用的新认识 总被引:7,自引:3,他引:4
冰川成冰作用的研究对于选择冰芯钻取点具有重要的科学意义。前人对珠穆朗玛峰北坡冰川成冰作用的研究,由于缺少高海拔区域的实测资料而具有一定的局限性。文章通过1998年东绒布冰川垭口处(6 500 m a. s. l.)11 m冰芯和海拔6 450 m处20 m冰芯剖面的成冰作用过程研究,认识到由于水、热条件的逐年波动,冰川成冰作用也处于变化之中。珠穆朗玛峰北坡东绒布冰川高海拔区域,在一定的水、热条件下(如气温较低和降水量较大等),再冻结-重结晶作用依然占主导地位,该成冰作用至少在垭口部位是有分布的。而一般在气温较高或降水量较少等条件下,冰川的成冰作用则以冷渗浸-重结晶作用为主。 相似文献
19.
近30年珠穆朗玛峰国家自然保护区冰川变化的遥感监测 总被引:18,自引:2,他引:16
利用1976、1988和2006年的3期陆地卫星遥感数据,采用面向对象的解译方法并结合专家知识分类规则自动提取珠穆朗玛峰国家自然保护区(以下简称珠峰保护区)3个时期的冰川信息,并利用遥感、地理信息系统和图谱的方法对冰川时空分布特征和变化及其原因与不确定性进行了分析。结果如下:(1)2006年珠峰保护区内冰川面积为2710.17±0.011km2,为研究区总面积的7.41%,主要分布在研究区南部海拔4700~6800m的高山区;(2)1976-2006年,珠峰保护区冰川持续退缩明显,总面积减少501.91±0.035km2,冰湖扩张迅速(净增加36.88±0.035km2);研究区南坡子流域冰川退缩率(16.79%)高于北坡子流域(14.40%);珠峰保护区冰川以退缩为主,退缩冰川主要分布于海拔4700~6400m,退缩区上限海拔为6600~6700m;(3)1976年以来,气温显著上升和降水减少是冰川退缩的关键因素。 相似文献