Abstract
The Karakoram has had an overall slight positive glacier mass balance since the end of 20th century, which is anomalous given that most other regions in High Mountain Asia have had negative changes. A large number of advancing, retreating, and surging glaciers are heterogeneously mixed in the Karakoram increasing the difficulties and inaccuracies to identify glacier surges. We found two adjacent glaciers in the eastern Karakoram behaving differently from 1995 to 2019: one was surging and the other was advancing. In order to figure out the differences existing between them and the potential controls on surges in this region, we collected satellite images from Landsat series, ASTER, and Google Earth, along with two sets of digital elevation model. Utilizing visual interpretation, feature tracking of optical images, and differencing between digital elevation models, three major differences were observed: (1) the evolution profiles of the terminus positions occupied different change patterns; (2) the surging glacier experienced a dramatic fluctuation in the surface velocities during and after the event, while the advancing glacier flowed in a stable mode; and (3) surface elevation of the surging glacier decreased in the reservoir and increased in the receiving zone. However, the advancing glacier only had an obvious elevation increase over its terminus part. These differences can be regarded as standards for surge identification in mountain ranges. After combining the differences with regional meteorological conditions, we suggested that changes of thermal and hydrological conditions could play a role in the surge occurrence, in addition, geomorphological characteristics and increasing warming climate might also be part of it. This research strongly contributes to the literatures of glacial motion and glacier mass change in the eastern Karakoram through remote sensing.
Highlights
As a key indicator of climate variability, changes in mountain glaciers contribute to sea-level rise and sometimes induce flood hazards to local and downstream residences [1,2,3,4]
After coregistering HMA digital elevation models (DEMs) and Shuttle Radar Topography Mission (SRTM) DEM, we found that there were still registration errors existing in the map of elevation differences
We discovered some outliers locating at high-elevation zones and steep slopes as a possible result of poor feature matching during photogrammetric generation of High Mountain Asia 8-meter DEM (HMA DEM)
Summary
As a key indicator of climate variability, changes in mountain glaciers contribute to sea-level rise and sometimes induce flood hazards to local and downstream residences [1,2,3,4]. Only a small number, less than 1%, of these mountain glaciers are surge-type glaciers [5], they play an important role in the research of flow instabilities and modern glacier processes [6,7]. Most surge-type glaciers undergo active phases and quiescent phases occurring in a way of quasiperiodic oscillation [8,9]. During the quiescent phases lasting years to decades, new ice is recharged in the reservoirs and the discharged ice in the receiving zones recedes progressively [9,11]. A rising number of literatures have been published focusing on their evolution and distribution [7,12,13,14]
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