We investigate the control of the morphological variables on the 2000–2016 glacier‐wide mass balances of 6,470 individual glaciers of High Mountain Asia. We separate the data set into 12 regions assumed to be climatically homogeneous. We find that the slope of the glacier tongue, mean glacier elevation, percentage of supraglacial debris cover, and avalanche contributing area all together explain a maximum of 48% and a minimum of 8% of the glacier‐wide mass balance variability, within a given region. The best predictors of the glacier‐wide mass balance are the slope of the glacier tongue and the mean glacier elevation for most regions, with the notable exception of the inner Tibetan Plateau. Glacier‐wide mass balances do not differ significantly between debris‐free and debris‐covered glaciers in 7 of the 12 regions analyzed. Lake‐terminating glaciers have more negative mass balances than the regional averages, the influence of lakes being stronger on small glaciers than on large glaciers.
The fate of the Hindu Kush Himalayan glaciers has been a topic of heated debate due to their rapid melting and retreat. The underlying reason for the debate is the lack of systematic large-scale observations of the extent of glaciers in the region owing to the high altitude, remoteness of the terrain, and extreme climatic conditions. Here we present a remote sensing -based comprehensive assessment of the current status and observed changes in the glacier extent of the Hindu Kush Himalayas. It reveals highly heterogeneous, yet undeniable impacts of climate change.
Abstract. Glacial lake outburst floods (GLOFs) are among the most
concerning consequences of retreating glaciers in mountain ranges worldwide.
GLOFs have attracted significant attention amongst scientists and
practitioners in the past 2 decades, with particular interest in the
physical drivers and mechanisms of GLOF hazard and in socioeconomic and other
human-related developments that affect vulnerabilities to GLOF events. This
increased research focus on GLOFs is reflected in the gradually increasing
number of papers published annually. This study offers an overview of recent
GLOF research by analysing 594 peer-reviewed GLOF studies published between
2017 and 2021 (Web of Science and Scopus databases), reviewing the content and
geographical focus as well as other characteristics of GLOF studies. This
review is complemented with perspectives from the first GLOF conference (7–9
July 2021, online) where a global GLOF research community of major
mountain regions gathered to discuss the current state of the art of
integrated GLOF research. Therefore, representatives from 17 countries
identified and elaborated trends and challenges and proposed possible ways
forward to navigate future GLOF research, in four thematic areas: (i) understanding GLOFs – timing and processes; (ii) modelling GLOFs and GLOF
process chains; (iii) GLOF risk management, prevention and warning; and (iv) human dimensions of GLOFs and GLOF attribution to climate change.
Changes in glacial lakes and the consequences of these changes, particularly on the development of water resources and management of glacial lake outburst flood (GLOF) risk, has become one of the challenges in the sustainable development of high mountain areas in the context of global warming. This paper presents the findings of a study on the distribution of, and area changes in, glacial lakes in the Koshi basin in the central Himalayas. Data on the number of glacial lakes and their area was generated for the years 1977, 1990, 2000, and 2010 using Landsat satellite images. According to the glacial lake inventory in 2010, there were a total of 2168 glacial lakes with a total area of 127.61 km 2 and average size of 0.06 km 2 in the Koshi basin. Of these, 47% were moraine dammed lakes, 34.8% bedrock dammed lakes and 17.7% ice dammed lakes. The number of glacial lakes increased consistently over the study period from 1160 in 1977 to 2168 in 2010, an overall growth rate of 86.9%. The area of glacial lakes also increased from 94.44 km 2 in 1977 to 127.61 km 2 in 2010, a growth rate of 35.1%. A large number of glacial lakes in the inventory are small in size (≤ 0.1 km 2). End moraine dammed lakes with area greater than 0.1 km 2 were selected to analyze the change characteristics of glacial lakes in the basin. The results show that, in 2010, there were 129 lakes greater than 0.1 km 2 in area; these lakes had a total area of 42.92 km 2 in 1997, increasing to 63.28 km 2 in 2010. The Decadal glacial lake changes in the Koshi basin, central Himalaya, from 1977 to 2010, derived from Landsat satellite images Finu SHRESTHA 1 *
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