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1.
西藏波密米堆冰湖溃决浅议 总被引:4,自引:0,他引:4
1988年7月15日西藏波密米堆终碛湖发生溃决,最大洪峰流量1270立方米/秒,溃决水量540万立方米,形成了大规模的泥石流-洪水灾害。冰湖溃决的原因是;终碛堤存在渗漏薄弱环节,堤内有埋藏冰;持续高温和冰川融水的潜热使埋藏冰融化,由潜蚀而迅速发展成管涌导致溃决。 相似文献
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《山地学报》2015,(6)
冰川终碛湖溃决引发的大规模山洪泥石流灾害,常给下游沿河一带造成重大人员伤亡和财产损失,受到社会广泛关注。冰川终碛湖一次溃决常未到底,其部分溃决后,残留湖因源头冰川进退、冰舌持续消融致后期湖面面积增大,湖水量增加,作者将这种现象定义为冰川终碛湖溃决-再生现象。以西藏波密米堆沟光谢错和聂拉木章藏布次仁玛错冰湖为研究对象,基于前人研究成果,利用遥感解译方法,分析了光谢错和次仁玛错冰湖面积的变化和冰川末端进退变化的特征。研究表明:光谢错、次仁玛错呈现出冰湖面积增大→溃决缩小→面积再增大的过程,光谢错在1988年溃决后面积已恢复至溃决前的63.6%,次仁玛错在1981年溃决后面积已基本恢复至溃决前的大小;从1980年代末至现在,贡扎冰川、阿玛次仁冰川末端处于退缩状态,终碛湖面积呈扩张状态。结合波密、聂拉木两气象站多年年降水量和年平均气温观测资料进行同步对比分析,初步探讨了冰川终碛湖再生现象的机理:1.冰川末端的前进与后退是冰湖面积变化的主导者,冰舌前进推动湖盆底冰碛物和溃口两侧岸坡垮塌导致堵塞泄流通道,冰川末端的退缩提供了空间条件;2.持续高温与强降雨的耦合作用是冰湖溃决的直接激发条件,持续高温累积是冰川消融冰湖面积增大的主要因素。 相似文献
3.
西藏喜马拉雅山区危险冰湖及其溃决特征 总被引:28,自引:1,他引:28
喜马拉雅山区的冰湖溃决主要属终碛湖溃决。野外考察和编目研究的结果表明,终碛湖占各类高山冰湖总数的1/2和总水体的3/4。鉴别出34个危险终碛湖,其水体容量在10×10~6—30×10~6m~3之间,平均水深31m,实测最大水深在70m左右。危险终碛湖绝大多数形成于小冰期最后一次冰退阶段,由于其形态特征和现代冰川的直接影响而具有潜在的溃决危险;讨论了终碛湖溃决的特征,主要因素及其周期性。 相似文献
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冰湖的界定与分类体系——面向冰湖编目和冰湖灾害研究 总被引:4,自引:0,他引:4
冰川湖泊(简称冰湖)不仅是高山区重要的水资源,而且是许多冰川灾害的孕育者和发源地,在冰冻圈科学、气候变化和山地灾害研究中具有重要地位。本文系统讨论了现有冰湖定义及存在的问题,从冰湖编目和冰湖灾害研究视角提出冰湖的定义,指出现有冰湖研究主要是基于“以现代冰川融水为主要补给源或在冰碛垄洼地内积水形成的天然水体”这一冰湖定义的。同时,从冰湖形成机理、地貌形态和空间分布位置将冰湖划分为冰川侵蚀湖(冰斗湖、冰川槽谷湖和其他冰川侵蚀湖)、冰碛阻塞湖(终碛阻塞湖、侧碛阻塞湖、冰碛垄热融湖)、冰川阻塞湖(冰川前进阻塞湖和其他冰川阻塞湖)、冰面湖、冰下(内)湖和其他冰川湖6大类及8个亚类,并给出各冰湖类型相应的遥感判识指标和定量指标,以期建立具有普适性和可操作性的冰湖分类体系。 相似文献
6.
西藏冰冻圈消融退缩现状及其对生态环境的影响 总被引:3,自引:2,他引:1
气候变暖是全球性问题,而西藏对全球变化的响应尤为剧烈。以西藏冰冻圈为研究对象,在已有研究成果基础上,论述了西藏冰冻圈的消融退缩与全球气候变化之间的关系,认为西藏冰冻圈消融与退缩是对全球气候变暖的直接响应。西藏冰冻圈的消融退缩对该区生态环境产生了重要影响,主要包括:冰川消融直接导致了河川径流量变化以及冰川型泥石流、冰湖溃决等灾害的频发;高原冻土层的消融导致了冻融侵蚀增强、高寒草甸以及高寒沼泽草甸的退化和种群演替,同时还导致了地表向干化方向发展,加剧了区域荒漠化趋势。 相似文献
7.
开展中—尼通道沿线冰川/冰湖变化及其相关灾害调查,对减少此类灾害发生、保障该地区安全、维护其在两国之间的经济、文化交流地位具有重要意义。中—尼通道地形陡峭复杂,现代冰川发育,在全球变暖的背景下冰川物质亏损显著,冰湖扩张明显,冰川相关灾害风险突出,已经引起国内外众多学者的广泛关注。本文主要运用遥感手段结合野外考察对中—尼通道沿线冰川及其相关灾害进行了初步调查,对直接影响干线通道的典型支沟流域上游冰川分布及其变化进行了统计,并初步分析了与冰川冰湖变化相关的灾害危险性。结论如下:中尼通道沿线13个子流域共发育冰川568条,总面积804.71 km~2,平均冰川覆盖率为12.89%,主要集中在海拔5000~6000 m,27年间(1991—2018年)三通道内的冰川平均退缩率达9.93%。共有冰湖74个,呈逐年扩张态势,20年间(1990—2010年)冰湖平均扩张率达86.5%,其中危险冰湖共计2个。三通道内近半个世纪以来共计发生冰川/冰湖相关灾害共计9起,未来有出现(次生)泥石流/滑坡、洪水、冰湖溃决等形式灾害的可能。发生于柯西河、吉隆藏布和甘达基河一些河段的各类灾害会对山区水库和相关水电设施造成重大影响。本研究可为探讨中—尼喜马拉雅山地区冰川/冰湖变化的时空特征、冰川相关灾害的引发机制以及可能灾害预估等提供资料参考。 相似文献
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冰湖溃决灾害是青藏高原地区主要的灾害之一。详细了解冰湖的面积和水量变化及其原因, 有助于更准确地确定其溃决的可能性和产生破坏的程度和范围。米堆冰湖为一个典型的冰碛物阻塞冰湖, 1988 年7 月15 日曾发生溃决。本研究利用1980 年1:5 万地形图和DEM、1988 年TM影像、2001 年IKONOS影像以及2001、2007、2009、2010 年ALOS影像, 提取冰湖溃决前后的面积变化, 结合野外实地测得的冰湖水深, 获得冰湖不同时期的水量及其变化。同时, 利用自动水位计, 监测湖泊相对水深的变化及其原因。结果显示, 米堆溃决前面积达到64×104 m2, 水量为699×104 m3, 溃决使得601.83×104 m3的水量溃出, 水位下降了17.18 m, 但溃决口并未达到冰湖最低处, 溃决后仍有97.17×104 m3的水量。近年来, 气温升高融水增加使得冰湖面积和水量不断增加, 按照目前的水量增加速率, 冰湖再次发生溃决的可能性较小, 而在由于其他原因使得冰湖发生堵塞或大量外来物质(冰川断裂、滑坡等)填充进冰湖时, 可能导致冰湖水位急剧上升, 再次发生溃决。 相似文献
9.
近20年天山地区冰湖变化特征 总被引:1,自引:1,他引:0
主要基于Landsat TM/ETM+影像等数据,分析1990-2010 年来天山地区冰湖变化特征及其对冰川融水径流的影响。近20 年来,天山冰湖面积平均以0.689 km2a-1 或0.8% a-1的速度扩张,其中一半以上是由东天山(0.352 km2 a-1) 贡献的,其次为北天山,面积年均增率为0.165km2 a-1,西天山和中央天山的面积年均增率最小,分别为0.089 km2 a-1和0.083 km2 a-1。除在相对较低海拔(< 2900 m) 和高海拔(> 4100 m) 范围内冰湖面积出现减少的现象,其他各高度带的冰湖面积均在扩张,其中增率最快的在3500~3900 m之间,平均增速达1.6% a-1。冰湖扩张是本区气候变暖和冰川普遍退缩共同作用的结果,以中小规模的冰湖(< 0.6 km2) 对冰川退缩响应最为敏感。冰湖扩张能在一定程度上延缓因气候变暖而导致的区域冰川水资源的亏损,每年大约有0.006 Gt 的冰川融水滞留在冰湖中,约占天山冰川年消融量的2‰,但也将加剧本区冰湖溃决洪水/泥石流灾害的频次和强度。 相似文献
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11.
Glacier retreat is not only a symbol of temperature and precipitation change, but a dominating factor of glacial lake changes in alpine regions, which are of wide concern for high risk of potential outburst floods. Of all types of glacial lakes, moraine-dammed lakes may be the most dangerous to local residents in mountain regions. Thus, we monitored the dynamics of 12 moraine-dammed glacial lakes from 1974 to 2014 in the Poiqu River Basin of central west Himalayas, as well as their associated glaciers with a combination of remote sensing, topographic maps and digital elevation models (DEMs). Our results indicate that all monitored moraine-dammed glacial lakes have expanded by 7.46 km2 in total while the glaciers retreated by a total of 15.29 km2 correspondingly. Meteorological analysis indicates a warming and drying trend in the Nyalam region from 1974 to 2014, which accelerated glacier retreat and then augmented the supply of moraine-dammed glacial lakes from glacier melt. Lake volume and water depth changed from 1974 to 2014 which indicates that lakes Kangxico, Galongco, and Youmojanco have a high potential for outburst floods and in urgent need for continuous monitoring or artificial excavation to release water due to the quick increase in water depths and storage capacities. Lakes Jialongco and Cirenmaco, with outburst floods in 1981 and 2002, have a high potential risk for outburst floods because of rapid lake growth and steep slope gradients surrounding them. 相似文献
12.
叶如藏布流域冰川和冰湖众多,冰川融水是当地重要的淡水资源,是冰湖扩张的重要补给,冰湖溃决是当地潜在的自然灾害,因此分析该区域冰川和冰湖的现状与变化特征具有重要的现实意义。基于Landsat系列遥感影像,分析1990—2020年叶如藏布流域冰川和冰湖的分布与变化特征。结果表明:(1) 近30 a来叶如藏布流域冰川面积整体呈退缩趋势,由1990年167.80 km2退缩到2020年128.92 km2,共退缩38.88 km2,年均退缩率为0.77%·a-1,且研究区冰川主要分布在海拔5800~6400 m之间,集中分布在5°~20°的坡度上。(2) 与冰川变化趋势相反,研究时段冰湖整体表现为扩张趋势,由1990年5.72 km2增加到2020年8.81 km2,30 a共增加3.09 km2,年均增长率为1.80%·a-1。(3) 冰湖主要分布在海拔5000~5600 m范围内,坡度在0~10°分布面积较多,表碛覆盖型冰川与非表碛覆盖型冰川对冰湖有着不同程度的影响。(4) 1990—2017年叶如藏布流域温度与降水波动较大,温度整体呈上升趋势,降水量则波动下降,导致叶如藏布流域的冰川消融,冰湖扩张。通过上述研究以期为叶如藏布流域地区提供详细的冰川和冰湖面积分布与变化特征基础数据,为防灾减灾提供一定的支撑。 相似文献
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我国喜马拉雅山区冰湖扩张特征及其气候意义 总被引:5,自引:1,他引:4
分析冰湖扩张特征和扩张方式及其气候意义,有利于认识冰川-冰湖-气候三者的变化关系和冰湖溃决灾害危险性程度。基于大比例尺地形图、DEM、ASTER影像等数据,分析近30年来我国喜马拉雅山区不同海拔高度冰湖变化的特征及冰湖-母冰川的相对位置的变化关系,探讨其气候效应。结果显示:(1) 存在冰湖的面积增大是冰湖面积扩张的主要贡献者,占总面积净增量的67%,新增湖的面积占总面积净增量的33%;(2) 不同高度带冰湖面积多呈扩张态势,净增面积在5000~5300 m出现峰值,指示气候变化的垂直差异性;(3) 在2000s 母冰川-冰湖距离为0 的冰湖,数量占扩张冰湖总数的19%,而其冰湖面积增量却占了总面积增量的60%,为冰湖扩张的主体,反映出冰湖与母冰川关系越紧密,气候效应越强烈,冰湖面积增加越显著。 相似文献
14.
Definition and classification system of glacial lake for inventory and hazards study 总被引:1,自引:0,他引:1
Glacial lakes are not only the important refresh water resources in alpine region, but also act as a trigger of many glacial hazards such as glacial lake outburst flood (GLOF) and debris flow. Therefore, glacial lakes play an important role on the cryosphere, climate change and alpine hazards. In this paper, the issues of glacial lake were systematically discussed, then from the view of glacial lake inventory and glacial lake hazards study, the glacial lake was defined as natural water mainly supplied by modern glacial meltwater or formed in glacier moraine’s depression. Furthermore, a complete classification system of glacial lake was proposed based on its formation mechanism, topographic feature and geographical position. Glacial lakes were classified as 6 classes and 8 subclasses, i.e., glacial erosion lake (including cirque lake, glacial valley lake and other glacial erosion lake), moraine-dammed lake (including end moraine-dammed lake, lateral moraine-dammed lake and moraine thaw lake), ice-blocked lake (including advancing glacier-blocked lake and other glacier-blocked lake), supraglacial lake, subglacial lake and other glacial lake. Meanwhile, some corresponding features exhibiting on remote sensing image and quantitative indices for identifying different glacial lake types were proposed in order to build a universal and operational classification system of glacial lake. 相似文献
15.
Glacial lakes are not only the important refresh water resources in alpine region, but also act as a trigger of many glacial hazards such as glacial lake outburst flood(GLOF) and debris flow. Therefore, glacial lakes play an important role on the cryosphere, climate change and alpine hazards. In this paper, the issues of glacial lake were systematically discussed, then from the view of glacial lake inventory and glacial lake hazards study, the glacial lake was defined as natural water mainly supplied by modern glacial meltwater or formed in glacier moraine's depression. Furthermore, a complete classification system of glacial lake was proposed based on its formation mechanism, topographic feature and geographical position. Glacial lakes were classified as 6 classes and 8 subclasses, i.e., glacial erosion lake(including cirque lake, glacial valley lake and other glacial erosion lake), moraine-dammed lake(including end moraine-dammed lake, lateral moraine-dammed lake and moraine thaw lake), ice-blocked lake(including advancing glacier-blocked lake and other glacier-blocked lake), supraglacial lake, subglacial lake and other glacial lake. Meanwhile, some corresponding features exhibiting on remote sensing image and quantitative indices for identifying different glacial lake types were proposed in order to build a universal and operational classification system of glacial lake. 相似文献
16.
The Himalayas are prone to glacial lake outburst floods, which can pose a severe threat to downstream villages and infrastructure. The Zhangmu and Gyirong land treaty ports are located on the China-Nepal border in the central Himalayas. In recent years, the expansion of glacial lakes has increased the threat of these two port regions. This article describes the results of mapping the glacial lakes larger than 0.01 km2 in the Zhangmu and Gyirong port regions and analyzes their change. It provides a comprehensive assessment of potentially dangerous glacial lakes and predicts the development of future glacial lakes. From 1988 to 2019, the glacial lakes in these port regions underwent "expansion", and moraine-dammed lakes show the most significant expansion trend. A total of eleven potentially dangerous glacial lakes are identified based on the assessment criteria and historical outburst events; most expanded by more than 150% from 1988 to 2019, with some by over 500%. The Cirenmaco, a moraine-dammed lake, is extremely prone to overtopping due to ice avalanches or the melting of dead ice in the dam. For other large lakes, such as the Jialongco, Gangxico and Galongco, ice avalanches may likely cause the lakes to burst besides self-destructive failure. The potential dangers of the Youmojianco glacial lakes, including lakes Nos. 9, 10 and 11, will increase in the future. In addition, the glacier-bed topography model predicts that 113 glacial lakes with a size larger than 0.01 km2, a total area of 11.88 km2 and a total volume of 6.37×109 m3 will form in the study area by the end of the 21 century. Due to global warming, the glacial lakes in the Zhangmu and Gyirong port regions will continue to grow in the short term, and hence the risk of glacial lake outburst floods will increase. 相似文献
17.
Changes in glacial lakes and glaciers of post-1986 in the Poiqu River basin, Nyalam, Xizang (Tibet) 总被引:16,自引:0,他引:16
Glacial lakes and glaciers are sensitive indicators of recent climate change. In the Poiqu River basin of southern Tibet, 60–100 km NW of Mt. Everest, Landsat imagery defines post-1986 changes in the size and distribution of both glacial lakes and glaciers. Total area of glaciers in the 229-km2 drainage area has decreased by 20%. The number of glacial lakes with areas in excess of 0.020 km2 has increased by 11%, and the total area of glacial lakes has increased by 47%. The areas of typical large glacial lakes of the area (Galongco, Gangxico, and Cirenmaco) have increased by 104, 118, and 156%, respectively, and these increases are confirmed by field investigations.Comparing the 1986 data, the area of glaciers in the basin headwaters has decreased by 46.18 km2 to a present total area of 183.12 km2, an annual rate of change of 3.30 km2/year. Trends indicate that the total area of glaciers will continue to decrease and that both the numbers and areas of glacial lakes will continue to increase. Accompanying these trends will be an increased risk of debris flows, formed by entrainment of sediment in glacial-outburst floods and in surges from both failure and avalanche- and landslide-induced overtopping of moraine dams. Based on both the local and world-wide history of catastrophes from flows of these origins, disaster mitigation must be planned and appropriate engineering countermeasures put in place as soon as possible. 相似文献
18.
Yeong Bae Seong Michael P. Bishop Andrew Bush Penny Clendon Luke Copland Robert C. Finkel Ulrich Kamp Lewis A. Owen John F. Shroder 《Geomorphology》2009,103(2):251-267
The Central Karakoram, which includes K2 in Pakistan, is one of the most rapidly rising areas on Earth and exhibits complex topography and extreme relief. Impressive valley fills and glacial landforms are present throughout the valleys. The dynamics of landscape evolution of the region are currently not well understood. Consequently, the landforms were mapped and assessed in the Skardu, Shigar, and Braldu valleys, to elucidate the spatio-temporal scale dependencies of surface processes active in the region. These valleys were examined using geomorphic field methods, remote sensing, geomorphometry, and terrestrial cosmogenic nuclides (TCNs) surface exposure dating. The glaciers in this region have oscillated considerably throughout the Late Quaternary, and four glacial stages have been recognized including at least six glacial advances. Surface processes readjusted after glacier retreat, and ubiquitous mass movements and catastrophic landsliding transported material from steep slopes to valley bottoms, while glaciofluvial meltwater and glacier outburst floods redistributed sediment down valley. Glacier geochronology and late Holocene ages of the outburst flood deposits indicate that landscape evolution has been dominated by glaciation and paraglaciation during the late Quaternary. 相似文献
19.
青藏高原可可西里地区现代冰川发育特征 总被引:5,自引:1,他引:5
经野外考察和室内分析计算,青藏可可西里地区发育现代冰川437条,覆盖面积达1552.39km^2,冰储量为162.8349km^3,成为本区众多河湖泊水体的重要补给源泉。 相似文献