Glacier branch lines and glacier ice thickness estimation for debris-covered glaciers in the Central Tien Shan

Information about the ice volume stored in glaciers is of high importance for sustainable water management in many arid regions of Central Asia. Several methods to estimate the ice volume exist. However, none of them take the specific characteristics of flat terminus debris-covered glaciers into acc...

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Bibliographic Details
Main Authors: Pieczonka, Tino, Bolch, Tobias, Kröhnert, Melanie, Peters, Juliane, Liu, Shiyin
Format: Article in Journal/Newspaper
Language:English
Published: International Glaciological Society 2018
Subjects:
Online Access:https://www.zora.uzh.ch/id/eprint/160119/
https://www.zora.uzh.ch/id/eprint/160119/1/2018_glacier_branch_lines_and_glacier_ice_thickness_estimation_for_debriscovered_glaciers_in_the_central_tien_shan.pdf
https://doi.org/10.1017/jog.2018.75
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Summary:Information about the ice volume stored in glaciers is of high importance for sustainable water management in many arid regions of Central Asia. Several methods to estimate the ice volume exist. However, none of them take the specific characteristics of flat terminus debris-covered glaciers into account. We present a method for deriving spatially-distributed ice thickness for debris-covered dendritic glaciers, which are common not only in Central Tien Shan but also in several other mountain ranges in High Asia. The method relies on automatically generated branch lines, observed surface velocities and surface topographic parameters as basic input. Branch lines were generated using Thiessen polygons and Dijkstra's path algorithm. Ice thicknesses for four debris-covered glaciers – South Inylchek, Kaindy, Tomur and Koxkar glaciers – have been estimated along the branch line network solving the equation of laminar flow. For Koxkar and South Inylchek glaciers, respectively, maximum thicknesses of ~250 and 380 m were estimated. These results differ by ~50 m compared with GPR measurements with an uncertainty for the debris-covered parts of ~40%. Based on geodetic mass balances, we estimate that the investigated glaciers lost between 6 and 28% of their volume from 1975 to the early 2000s.