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1.
Flood and sediment disasters caused by glacial lake outbursts have occurred frequently in recent years in the Himalayas of Nepal. Glacial lake outburst floods (GLOFs) can cause catastrophic flooding in downstream areas with serious damage to lives and property. It is thus important to investigate outburst floods from potentially dangerous glacial lakes. In this study, the characteristics of potential outburst floods from the Tsho Rolpa glacial lake due to two types of moraine dam failure caused by seepage flow or water overtopping were analyzed with various scenarios by using integrated modeling system of three numerical models: (1) the flow and bed-surface erosion model, (2) the seepage model and (3) the slope stability model. Flood inundation areas were also identified by using the numerical model of the flow and moraine dam failure and geographical information system tools. Possible threats and damages due to the potential GLOF events from the lake were also analyzed based on numerical results, flood inundation maps and field investigations. 相似文献
2.
希夏邦马峰东坡冰川与冰川湖泊变化遥感监测 总被引:21,自引:9,他引:12
1977-2003年的遥感影像显示,希夏邦马峰东坡的冰川在迅速退缩,而其相应的冰川湖泊在迅速增大.南部的吉葱普冰川每年的退缩速度57099 m2,冰舌退缩48 m·a-1,相应的卢姆池米冰湖面积增加速度大约为79048 m2·a-1;北面的热强冰川退缩速度在63224 m2·a-1,冰舌退缩71 m·a-1,相应的扛西错冰湖面积增加约73 425 m2·a-1.从这两个冰湖的类型和变化分析,认为其具有发生冰川湖泊溃决洪水的潜在危险. 相似文献
3.
Gohar Rehman Sajjad Ahmad Shuhab D. Khan Fayaz Ali Taqweemul H. Ali Sadaf F. Khan 《Natural Hazards》2014,70(2):1589-1602
Glacial lake outburst flood (GLOF) is a powerful natural phenomenon that is very active in the Karakoram and Himalayas. This paper presents a case study from Gupis Tehsil in northern areas of Pakistan that is exposed to GLOFs from nine different glacial lakes in its upper catchment areas. Khukush Lake being the largest of all the glacial lakes has been studied and a flood attenuation model has been created for the whole Gupis Tehsil. This lake covers almost 2.2 km2 of surface area, and its calculated volume is 2.6 × 104 m3. In case of its outburst, the peak flow discharge is calculated to be 7,642 m3/s. The catchment area which contributes water and debris to the lake is 170 km2. This lake is dammed by a glacial moraine, which is not strong enough to sustain the pressure for a longer period of time. Other factors that are reducing the reliability of the dam are the secondary hazards which are in direct contact with the lake, and in case of their reactivation, they can put severe impacts on the dam. There are eight potential sites of the snow avalanche activity where debris along with snow may fall directly into the lake producing a strong wave. This strong wave of water will increase the pressure on the dam and ultimately will increase the probability for its outburst. The presense of water springs towards the downstream side of the natural dam also indicate the presence of hidden channels passing through the dam which may weaken the shear strength of the dam. Almost 24 villages settled along either sides of the Gupis River are critically studied for the expected flood from Khukush Lake. With few exceptions, almost 20–25 % area of all the villages will be affected from this flood. 相似文献
4.
亚洲高山区冰湖溃决洪水事件回顾 总被引:3,自引:1,他引:2
冰湖溃决洪水是由冰湖快速大量释水所导致的自然灾害。在全球变暖背景下,亟待建立完整的冰湖溃决洪水数据库,以进一步对冰湖进行危险性评估和风险管理。整理了亚洲高山区(青藏高原及周边地区)的冰湖溃决洪水资料,得出冰湖溃决洪水主要分布在天山山脉、喀喇昆仑山、喜马拉雅山脉、念青唐古拉山、横断山等区域。20世纪以来,亚洲高山区共计发生冰湖溃决洪水277起,其中冰碛湖溃决洪水113起,冰坝湖溃决洪水164起。导致冰碛湖溃决的诱因以冰-雪崩或冰川滑塌为主导,占50.1%,埋藏冰融化或管涌、强降水或上游来水、滑坡-岩崩以及地震占比分别为23.1%、18.5%、7.4%和0.9%。1980年以来,冰碛湖溃决洪水的发生频率呈较弱的增长趋势;但由于发生溃决的冰湖趋于小型化,其溃决水量与洪峰流量在喜马拉雅山脉、天山山脉等地区呈显著下降趋势。2010—2018年间喜马拉雅山脉中段发生8起冰湖溃决洪水事件,远高于天山山脉、喜马拉雅山脉东段和念青唐古拉山等地区,成为新的高发区,是未来重点关注的地区。在未来冰湖溃决洪水频率可能增加的状况下,相关国家和地区在应对冰川灾害、实现区域防灾减灾等方面需要加强沟通交流,共同建立跨区域协调的防灾体系。 相似文献
5.
Impressive flood deposits are described resulting from a catastrophic lake outburst in the Upper Chandra valley in the Lahul Himalaya, northern India. Reconstructions of the former glacial lake, Glacial Lake Batal, and the discharges were undertaken using landforms and sediment data. The glacial dam burst released 1.496 km3 of water in 0.72 days, with peak discharges of between 21000 and 27000 m3 s−1 at Batal. Dating by OSL suggests the flood occurred ca. 36.9 ± 8.4 to 43.4 ± 10.3 ka ago. This cataclysmic flood was responsible for major resedimentation and landscape modification within the Chandra valley. 相似文献
6.
冰湖溃决型泥石流是高原山区特殊的地质灾害,以西藏聂拉木县嘉龙湖为例,建立了一套冰湖溃决型泥石流危险性评价方法.以喜马拉雅山区1970—2015年气温波动频次和聂拉木冰湖溃决历史事件预测了未来10年嘉龙湖溃决的时间概率.利用遥感影像识别嘉龙湖上方不稳定冰体的范围和规模,采用美国土木工程师协会推荐公式和修正的三峡库区涌浪计算方法分析了冰川滑坡产生的涌浪规模,从涌浪波压力和越顶水流推力两方面预测了冰碛坝发生失稳的可能性.采用FLO-2D模拟冰湖溃决泥石流的运动过程,以最大流速和泥深表达了嘉龙湖溃决泥石流的危险程度.评价结果表明:2002年嘉龙湖溃决事件与当年气温偏高有关,未来嘉龙湖发生溃决概率高;冰川滑坡激起涌浪能够翻越坝顶,并引起坝体快速侵蚀而溃决;冰湖溃决泥石流对聂拉木县城河道两侧54栋建筑造成威胁.评价方法实现了冰湖溃决型泥石流危险性的定量分析,评价结果对聂拉木县城泥石流防灾具有现实意义. 相似文献
7.
Glacial lakes of the Hinku and Hongu valleys, Makalu Barun National Park and Buffer Zone, Nepal 总被引:1,自引:0,他引:1
Alton C. Byers Daene C. McKinney Marcelo Somos-Valenzuela Teiji Watanabe Damodar Lamsal 《Natural Hazards》2013,69(1):115-139
In recent decades, many of the larger glaciers in the Himalaya and Andes that have experienced increased melting have become glacial lakes. Some of these lakes present a risk of glacial lake outburst floods that can unleash stored lake water and eroded debris, often causing enormous devastation downstream. Many of these new glacial lakes have formed in the Mt. Everest and Makalu Barun National Parks of Nepal, nine of which in the remote Hinku and Hongu valleys have been designated as “potentially dangerous” based on remote sensing analyses. Until recently, however, relatively little ground-based information was available for these lakes, including their physical characteristics, danger level, prospective downstream impacts in the event of an outburst, and mitigation methods appropriate and applicable to remote regions within the Nepal Himalaya. This paper describes three separate, interdisciplinary expeditions to the Hinku and Hongu valleys between 2009 and 2012 that were designed to close these information gaps. Each expedition combined remote sensing with field-based analyses, repeat photography, interviews with local people, bathymetric surveys, ground penetrating radar, and flood modeling. Eight of the “potentially dangerous” lakes surveyed were found to be stable, and one that had escaped mention in previous studies (L464) was found to contain a high risk of an outburst flood. In the data-deficient high mountain world, we suggest that the combined use of sophisticated remote sensing and modeling technologies with traditional, field-based methods can provide the most thorough understanding of glacial lakes possible at this time, including the actual risks that they pose as well as the most appropriate and community-based risk reduction strategies. 相似文献
8.
尼泊尔4·25地震震前冰湖制图与潜在危险性分析 总被引:5,自引:1,他引:4
由于地震灾害的影响,冰湖上游的冰滑坡、冰崩、滑坡、泥石流会进入湖泊,通过冲击波或抬高水位,造成冰川坝或冰碛坝突然垮塌导致冰湖迅速排水而形成洪水或洪水泥石流.首先基于Landsat8遥感影像通过人工目视解译的方法构建尼泊尔2015年4月25日地震震前冰湖数据,为我国和尼泊尔的抗震救灾提供重要的数据支撑.然后利用历史遥感数据解译获取研究区2015年以前的历史冰湖数据,对历史冰湖数据和2015年的冰湖数据进行地理空间分析,计算其面积变化和长度变化.最后结合尼泊尔2015年4月25日地震峰值地面加速度数据通过空间分析识别地震影响区的潜在危险冰湖.研究表明:研究区面积0.02 km~2的冰湖有1 847个,面积263.18 km~2,其中快速变化冰湖87个,位于地震影响区的潜在危险冰湖49个,应重点关注潜在危险冰湖. 相似文献
9.
西藏喜马拉雅山地区冰湖溃决的预测模型及其应用研究 总被引:2,自引:1,他引:1
以西藏喜马拉雅山地区的冰湖为研究对象,基于现有的冰湖溃决预测方法,提出了建立冰湖溃决预测方法的关键点,即选取的指标必须能够体现冰湖的动态变化特征.在定量分析的建模过程中应该采用不确定性的数学理论,对于冰湖溃决可能性的等级划分需要进行合理性及实用性验证.选取坝顶宽度、湖水面距坝顶高度与坝高之比、冰湖面积和补给冰川面积为预测指标,通过对西藏喜马拉雅山地区29个冰湖样本进行逻辑回归分析,建立了冰湖溃决的预测模型,并用所有样本进行了交叉验证.结果表明:该模型能够在分类应用中取得较好效果,根据溃决冰湖累积百分数随冰湖溃决可能性大小的变化曲线,将冰湖溃决的可能性划分为四个等级.以黄湖为例,把湖水面距坝顶高度与坝高之比作为冰湖溃决的诱变指标,分析了冰湖溃决可能性大小的变化规律.结合现有的冰湖溃决预测的定性方法,讨论了所建立的冰湖溃决预测模型的优点和缺点. 相似文献
10.
Sherpa Sonam Futi Shrestha Milan Eakin Hallie Boone Christopher G. 《Natural Hazards》2019,96(2):607-626
Glacial lake outburst floods (GLOFs) are among the most serious cryospheric hazards for mountain communities. Multiple studies have predicted the potential risks posed by rapidly expanding glacial lakes in the Sagarmatha (Mt. Everest) National Park and Buffer Zone of Nepal. People’s perceptions of such cryospheric hazards can influence their actions, beliefs, and responses to those hazards and associated risks. This study provides a systematic approach that combines household survey data with ethnography to analyze people’s perceptions of GLOF risks and the socioeconomic and cultural factors influencing their perceptions. A statistical logit model of household data showed a significant positive correlation between the perceptions of GLOF risks and livelihood sources, mainly tourism. Risk perceptions are also influenced by spatial proximity to glacial lakes and whether a village is in potential flood zones. The 2016 emergency remediation work implemented in the Imja Tsho (glacial lake) has served as a cognitive fix, especially in the low-lying settlements. Much of uncertainty and confusions related GLOF risks among locals can be attributed to a disconnect between how scientific information is communicated to the local communities and how government climate change policies have been limited to awareness campaigns and emergency remediation efforts. A sustainable partnership of scientists, policymakers, and local communities is urgently needed to build a science-driven, community-based initiative that focuses not just in addressing a single GLOF threat but develops on a comprehensive cryospheric risk management plan and considers opportunities and challenges of tourism in the local climate adaptation policies.
相似文献11.
We present evidence of a large lake (Glacial Lake Victoria) that existed in Victoria Valley in the dry valleys region of Antarctica between at least 20 000 and 8600 14C yr BP. At its highstands, Glacial Lake Victoria covered 100 km2 and was ca. 200 m deep. The chronology for lake‐level changes comes from 87 AMS radiocarbon dates of lacustrine algae preserved in deltas and glaciolacustrine deposits that extend up to 185 m above present‐day lakes on the valley floor. The existence of Glacial Lake Victoria, as well as other large lakes in the dry valleys, indicates a climate regime significantly different from that of today at the last glacial maximum and in the early Holocene. Copyright © 2002 John Wiley & Sons, Ltd. 相似文献
12.
末次冰期以来,气候变暖导致全球高山地区的冰川环境变化剧烈,冰碛湖稳定性降低导致溃决频率增加,成为中国、尼泊尔、俄罗斯、秘鲁等10多个国家和地区频繁发生的冰川灾害类型之一。冰碛湖溃决诱发形成的洪水和泥石流,由于规模巨大、成灾速度快和波及范围广等特点,造成下游地区的基础设施和生命财产遭受惨重损失。本文通过对国内外冰碛湖溃决事件、溃决诱因、溃决模式和溃决洪水特征4个方面研究现状和发展现状的梳理和分析,总结经验和思路,从而为冰碛湖溃决研究和评价提供借鉴和参考。 相似文献
13.
Glacial lakes and glacial lake outburst flood in a Himalayan basin using remote sensing and GIS 总被引:1,自引:0,他引:1
Sanjay K. Jain Anil K. Lohani R. D. Singh Anju Chaudhary L. N. Thakural 《Natural Hazards》2012,62(3):887-899
Glacial hazards relate to hazards associated with glaciers and glacial lakes in high mountain areas and their impacts downstream. The climatic change/variability in recent decades has made considerable impacts on the glacier life cycle in the Himalayan region. As a result, many big glaciers melted, forming a large number of glacial lakes. Due to an increase in the rate at which ice and snow melted, the accumulation of water in these lakes started increasing. Sudden discharge of large volumes of water with debris from these lakes potentially causes glacial lake outburst floods (GLOFs) in valleys downstream. Outbursts from glacier lakes have repeatedly caused the loss of human lives as well as severe damage to local infrastructure. Monitoring of the glacial lakes and extent of GLOF impact along the downstream can be made quickly and precisely using remote sensing technique. A number of hydroelectric projects in India are being planned in the Himalayan regions. It has become necessary for the project planners and designers to account for the GLOF also along with the design flood for deciding the spillway capacity of projects. The present study deals with the estimation of GLOF for a river basin located in the Garwhal Himalaya, India. IRS LISSIII data of the years 2004, 2006 and 2008 have been used for glacial lake mapping, and a total of 91 lakes have been found in the year 2008, and out of these, 45 lakes are having area more than 0.01?km2. All the lakes have been investigated for vulnerability for potential bursting, and it was found that no lake is vulnerable from GLOF point of view. The area of biggest lake is 0.193, 0.199 and 0.203?km2 in the years 2004, 2006 and 2008, respectively. Although no lake is potentially hazardous, GLOF study has been carried out for the biggest lake using MIKE 11 software. A flood of 100-year return period has been considered in addition to GLOF. The flood peak at catchment outlet comes out to be 993.74, 1,184.0 and 1,295.58 cumec due to GLOF; 3,274.74, 3,465.0 and 3,576.58 cumec due to GLOF; and 100-year return flood together considering breach width of 40, 60 and 80?m, respectively. 相似文献
14.
J. Klimeš J. Novotný I. Novotná B. Jordán de Urries V. Vilímek A. Emmer T. Strozzi M. Kusák A. Cochachin Rapre F. Hartvich H. Frey 《Landslides》2016,13(6):1461-1477
Studies focusing on moraine deposits which slide into glacial lakes are scarce, even though they can trigger impact waves responsible for generating glacial lake outburst floods. We focused on landslides in lateral moraines as possible triggers. Detailed geomorphological, geophysical, and satellite radar interferometric investigations of the Palcacocha Lake moraine (Cordillera Blanca, Peru) together with laboratory tests on samples from the site provided data for slope stability calculations using GeoSlope software and hydrodynamic impact wave modeling using the Iber code. We identified landslides that could affect Palcacocha Lake and calculated their stability (factor of safety) under specified conditions, including variable water saturation and earthquake effects. Calculations showed that the moraine slopes are close to the threshold value (Fs?=?1) for stability and are especially sensitive to water saturation. The height of impact waves triggered by a landslide in 2003 and the potential wave heights from newly identified, possibly active landslides were calculated, based on landslide volume estimates, detailed lake bathymetry, and basin topography. Results show that potential future landslide-triggered waves could have similar properties to the 2003 impact wave. Evidence gathered in this study suggests that glacial lake outburst floods triggered by landslides from moraines, however, would be probably smaller than floods resulting from other types of slope processes (e.g., ice/rock avalanches) if dam breach is not taken into account. This assumption has to be critically evaluated against site-specific conditions at a given lake and any possible environmental factors, such as climate change or earthquake that may mobilize larger volumes of moraine material. 相似文献
15.
冰川-冰湖耦合过程是冰冻圈物质与能量循环的重要组成部分,系统刻画冰川演化与冰湖发育过程的相互作用机制,对于完善冰冻圈科学理论体系和认知冰川作用区变化规律、水循环模式和灾害效应具有重要意义。本文立足山地冰川演化和冰湖发育过程,系统归纳了冰川-冰湖相互作用研究进展,剖析了冰川作用与冰湖发育耦合机制及相关模型的应用,并对现有冰川演化与冰湖发育过程耦合机制研究存在的不足与挑战进行解析和总结。冰川-冰湖耦合过程的深入研究有助于提高数值模拟的可信度与精度,为评估冰川-冰湖耦合过程影响、建立灾害监测预警体系和采取适应性措施提供数据与理论基础。 相似文献
16.
Monitoring of Bashkara Glacier lakes (Central Caucasus, Russia) and modelling of their potential outburst 总被引:2,自引:1,他引:1
D. A. Petrakov O. V. Tutubalina A. A. Aleinikov S. S. Chernomorets S. G. Evans V. M. Kidyaeva I. N. Krylenko S. V. Norin M. S. Shakhmina I. B. Seynova 《Natural Hazards》2012,61(3):1293-1316
Glacier lakes pose threat to downstream settlements and infrastructure. In recent decades the number and area of lakes have
been growing at an accelerating rate due to worldwide glacier shrinkage. In the Russian Caucasus this process is understudied.
We present results obtained during a 12-year (1999–2010) continuous field monitoring of the Bashkara proglacial lakes group,
which we identified as the place with the highest GLOF risk in the region. Recession of the parent Bashkara Glacier was the
main driver of the rapid expansion of the lower Lake Lapa. The upper Lake Bashkara has not been enlarging, but its water level
has shown significant inter- and intra-annual fluctuations. The lake outburst probability has increased in recent years, and
in 2008 we observed surface overflow over the moraine dam. Taking into account that in the late 1950s lake outbursts at this
site led to large-scale glacial debris flows, we have simulated a potential outburst using River and FLO-2D software and carried
out hazard zonation. An early warning system has been designed and established at Lake Bashkara, and measures to mitigate
risk have been proposed. Rapid change of proglacial lakes requires regular monitoring in ‘hot spot’ areas where the GLOF hazard
is high and is dynamically changing. 相似文献
17.
Vít Vilímek Marco Luyo Zapata Jan Klimeš Zdeněk Patzelt Nelson Santillán 《Landslides》2005,2(2):107-115
In this article we describe natural hazards associated with outburst floods of Palcacocha Lake and landslide events on the slopes of its moraine dam, in Cojup Valley, Cordillera Blanca (Peru). These events occurred in the last 70 years and some of them resulted in disasters, which strongly affected the city of Huarás. Field investigations and reference expression hydrodynamic tests as well as archive satellite images and aerial pictures were used to describe the evolution of hazards connected with Palcacocha Lake. Expression hydrodynamic tests proved a high permeability of sandy gravels glacial sediments, which form the present-day lake dam. Seepage through the natural dam forming small ponds below the overflow spillways occurs. A retreat of the glacial tongue causing an increase of the lake volume and unloading of the slope toe areas are the most important recent processes that influence the potential hazards affecting the Cojup valley. The research has proved that the climate warming and ongoing deglaciation play a very significant role in the change of natural hazards conditions in high mountains. 相似文献
18.
Glacial lakes represent a threat for the populations of the Andes and numerous disastrous glacial lake outburst floods (GLOFs) occurred as a result of sudden dam failures or dam overtoppings triggered by landslides such as rock/ice avalanches into the lake. This paper investigates a landslide-triggered GLOF process chain that occurred on February 23, 2020, in the Cordillera Vilcabamba in the Peruvian Andes. An initial slide at the SW slope of Nevado Salkantay evolved into a rock/ice avalanche. The frontal part of this avalanche impacted the moraine-dammed Lake Salkantaycocha, triggering a displacement wave which overtopped and surficially eroded the dam. Dam overtopping resulted in a far-reaching GLOF causing fatalities and people missing in the valley downstream. We analyze the situations before and after the event as well as the dynamics of the upper portion of the GLOF process chain, based on field investigations, remotely sensed data, meteorological data and a computer simulation with a two-phase flow model. Comparison of pre- and post-event field photographs helped us to estimate the initial landslide volume of 1–2 million m3. Meteorological data suggest rainfall and/or melting/thawing processes as possible causes of the landslide. The simulation reveals that the landslide into the lake created a displacement wave of 27 m height. The GLOF peak discharge at the dam reached almost 10,000 m3/s. However, due to the high freeboard, less than 10% of the lake volume drained, and the lake level increased by 10–15 m, since the volume of landslide material deposited in the lake (roughly 1.3 million m3) was much larger than the volume of released water (57,000 m3, according to the simulation). The model results show a good fit with the observations, including the travel time to the uppermost village. The findings of this study serve as a contribution to the understanding of landslide-triggered GLOFs in changing high-mountain regions.
相似文献19.
Flow dynamics,sedimentation and erosion of glacial lake outburst floods along the Middle Pleistocene Scandinavian Ice Sheet (northern central Europe) 
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下载免费PDF全文 Jutta Winsemann Petteri Alho Leena Laamanen Nils Goseberg Jörg Lang Josef Klostermann 《Boreas: An International Journal of Quaternary Research》2016,45(2):260-283
During the Middle Pleistocene late Saalian glaciation of northern central Europe numerous pro‐glacial lakes formed along the southwestern margin of the Scandinavian Ice Sheet. Little is known about the drainage history of these lakes, the pathways of glacial lake outburst floods and their impacts on erosion, sedimentation and landscape evolution. This study investigated the impact of the late Saalian Weser and Münsterland Lake (Germany) outburst floods. In particular, we reconstructed the routing and flow dynamics of the lake outburst flood and analysed the flood related sediments. We employed one‐dimensional hydraulic modelling to calculate glacial lake outburst flood hydrographs. We modelled the flow pathway and local flow conditions along the pathway based on the boundary conditions of two different hydrographs and two different ice‐margin positions. The modelling results were compared with geomorphological and sedimentological field data in order to estimate the magnitude and impact of the flood on erosion and sedimentation. Two major lake drainage events are reconstructed for the study area, during which approximately 90–50 km3 of water was released. Modelling results indicate that the lake outburst floods created a high‐energy flood wave with a height of 35–50 m in confined valley areas that rapidly spread out into the Lower Rhine Embayment eventually flowing into the North Sea basin. The sedimentary record of the outburst floods comprises poorly sorted coarse‐grained gravel bars, long‐wavelength bedforms and sandy bedforms deposited by supercritical and subcritical flows. Some parts of the sandy flood deposits are rich in reworked mammoth bones or mammoth and horse teeth, pointing to reworking of older fluvial sediments, hydraulic concentration and subsequent re‐sedimentation of vertebrate remains. These deposits are preserved in sheltered areas or at high elevations, well above the influence of postglacial fluvial erosion. The flood‐related erosional features include up to 80‐m‐deep scour pools, alluvial channels and streamlined hills. 相似文献
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Within the past fifteen years, glacial lake outburst floods have become an activetopic of discussion within the development community focused on Nepal. Suchfloods endanger thousands of people, hundreds of villages, and basic infrastructuresuch as trails and bridges. The flood risk is also a major impediment to hydroelectricdevelopment in several river basins. Unlike most other mountain hazards in Nepal,reducing the possibility of outburst floods is technically feasible. The first attemptwithin Nepal to reduce the hazard of one lake by artificially lowering its water levelwas partially completed in June 2000. Completing this task and beginning work onother hazardous lakes will require difficult decisions about risk by downstream residentsand substantial investment from the international aid community. 相似文献