Comparison of modelled-and remote sensing-derived daily snow line altitudes at Ulugh Muztagh,northern Tibetan Plateau

作     者：Marinka SPIESS Eva HUINTJES Christoph SCHNEIDER 

作者机构：Department of GeographyRWTH Aachen UniversityWiillnerstr.5b52066 AachenGermany Humbold University BerlinUnter den Linden 610099 BerlinGermany 

出 版 物：《Journal of Mountain Science》 (山地科学学报（英文）)

年 卷 期：2016年第13卷第4期

页      面：593-613页

核心收录：

学科分类：07[理学] 070601[理学-气象学] 0706[理学-大气科学] 

基　　金：supported by the German Research Foundation(DFG)Priority Programme 1372,‘Tibetan Plateau:Formation Climate Ecosystems’through the DynRG-TiP(‘Dynamic Response of Glaciers on the Tibetan Plateau to Climate Change’)project under codes SCHN 680/3-3 and SCHE 750/4-3 the German Federal Ministry of Education and Research(BMBF)Central Asia Monsoon Dynamics and GeoEcosystems(CAME)program,through the WET project(‘Variability and Trends in Water Balance Components of Benchmark Drainage Basins on the Tibetan Plateau’)under code 03G0804A 

主　　题：Ulugh Muztagh Imaging spectroradiometer MODIS COSIMA Energy balance Snow line Tibetan Plateau Kunlun Shan 

摘      要：The ice cap Ulugh Muztagh in the central Kunlun Shan at the northern fringe of the Tibetan Plateau is a very isolated region with arid cold conditions. No observational, meteorological or glaciological ground truth data is available. Using the Moderate-resolution Imaging Spectroradiometer(MODIS) Level 1 radiance Swath Data(MOD02QKM) with a spatial resolution of 250 m, transient snow lines during the months of July to September in 2001 to 2014 are derived. Results are used to calibrate the physical based Coupled Snowpack and Ice surface energy and Mass balance model(COSIMA). The model runs on a representative detail region of Ulugh Muztagh(UM) on a digital elevation model with the same spatial resolution as the MODIS bands. In the absence of field observations, the model is driven solely by dynamically downscaled global analysis data from the High Asia Refined analysis(HAR). We compare remote sensing derived and modelled mean regional transient snow line altitudes in the course of consecutive summer seasons in 2008 to 2010. The resulting snow line altitude(SLA) and annual equilibrium line altitude(ELA) proxy of both methods coincide very well in their interannual variability in accordance with interannual variability of climatic conditions. Since SLAs of both methods do notconsistently agree on a daily basis a usage of remote sensing derived SLAs for model calibration in the absence of field observation data is only limitedly feasible for daily analysis. ELA approximation using the highest SLA at the end of ablation period may not be applied to UM because the negative winter mass balance(MB) is not reflected in the summer SLA. The study reveals moderate negative MB for UM throughout the modelling period. The mean regional MB of UM accounts for-523±410 mm w.e. a-1 in the modelling period. Hence UM seems not to belong to the area of the ‘Karakorum anomaly comprising a region of positive mass balances in recent years which has its centre presumably in the Western Kunlu