Three Recent and Lesser-Known Glacier-Related Flood Mechanisms in High Mountain Environments

IF 1.7 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Mountain Research and Development Pub Date : 2022-05-03 DOI:10.1659/MRD-JOURNAL-D-21-00045.1

A. Byers, D. Shugar, M. Chand, C. Portocarrero, M. Shrestha, D. Rounce, Teiji Watanabe

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引用次数: 2

Abstract

Glacial lake outburst floods, and specifically those triggered by avalanche-induced seiche waves, have been studied in considerable detail during the past several decades. Less attention has been given to other cryospheric flood phenomena, which include floods sourced primarily from englacial conduits, permafrost-linked rockfall and avalanches, and earthquake-triggered glacial lake floods. The article reviews examples of each phenomenon, based on field sampling and laboratory analyses, that have occurred in the Nepal Himalaya during the past decade, drawing parallels with similar events in other countries throughout the high mountain world. In most cases, the frequency of these events appears to be increasing globally, as is their potential to inflict significant damage downstream. We argue that each type of glacier flood requires more detailed study to develop the most effective prevention, mitigation, and adaptation approaches possible. Such studies will most likely be strengthened if they include a reconnaissance of the event as soon after its occurrence as possible, along with the participation, insights, and experience of local people, in addition to the use of increasingly powerful remote sensing technologies. How scientists can more quickly and effectively share the results of their research with decision-makers, and how decision-makers and governments can deliver more timely mitigation programs, are areas that also require further strengthening.

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高山环境中与冰川有关的三种最新和鲜为人知的洪水机制

在过去的几十年里，人们对冰湖溃决洪水，特别是由雪崩引发的海啸引发的溃决洪水进行了相当详细的研究。对其他冰冻圈洪水现象的关注较少，其中包括主要来自冰川管道的洪水，与永久冻土有关的岩崩和雪崩，以及地震引发的冰湖洪水。这篇文章基于实地取样和实验室分析，回顾了尼泊尔喜马拉雅地区在过去十年中发生的每一种现象的例子，并与整个高山世界其他国家的类似事件进行了比较。在大多数情况下，这些事件的频率似乎在全球范围内增加，因为它们有可能对下游造成重大损害。我们认为，每种类型的冰川洪水都需要更详细的研究，以制定最有效的预防、缓解和适应方法。如果这些研究包括在事件发生后尽快对其进行侦察，加上当地人民的参与、见解和经验，以及使用日益强大的遥感技术，那么这些研究很可能得到加强。科学家如何能够更快、更有效地与决策者分享他们的研究成果，以及决策者和政府如何能够提供更及时的缓解方案，这些领域也需要进一步加强。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mountain Research and Development 地学-环境科学

CiteScore

3.10

自引率

18.80%

发文量

审稿时长

4.5 months

期刊介绍： MRD features three peer-reviewed sections: MountainDevelopment, which contains “Transformation Knowledge,” MountainResearch, which contains “Systems Knowledge,” and MountainAgenda, which contains “Target Knowledge.” In addition, the MountainPlatform section offers International Mountain Society members an opportunity to convey information about their mountain initiatives and priorities; and the MountainMedia section presents reviews of recent publications on mountains and mountain development. Key research and development fields: -Society and culture- Policy, politics, and institutions- Economy- Bio- and geophysical environment- Ecosystems and cycles- Environmental risks- Resource and land use- Energy, infrastructure, and services- Methods and theories- Regions