Please wait a minute...
Journal of Arid Land
Journal of Arid Land  2023, Vol. 15 Issue (6): 637-648    DOI: 10.1007/s40333-023-0016-5     CSTR: 32276.14.s40333-023-0016-5
Research article     
Seasonal variations in glacier velocity in the High Mountain Asia region during 2015-2020
ZHANG Zhen1,*(), XU Yangyang1, LIU Shiyin2, DING Jing1, ZHAO Jinbiao1
1School of Geomatics, Anhui University of Science and Technology, Huainan 232001, China
2Institute of International Rivers and Eco-Security, Yunnan University, Kunming 650091, China
Download: HTML     PDF(4417KB)
Export: BibTeX | EndNote (RIS)      

Abstract  

Velocity is an important component of glacier dynamics and directly reflects the response of glaciers to climate change. As a result, an accurate determination of seasonal variation in glacier velocity is very important in understanding the annual variation in glacier dynamics. However, few studies of glacier velocity in the High Mountain Asia (HMA) region were done. Along these lines, in this work, based on Sentinel-1 glacier velocity data, the distribution of glacier velocity in the HMA region was plotted and their seasonal variations during 2015-2020 were systematically analysed. The average glacier velocity in the HMA region was 0.053 m/d, and was positively correlated with the glacier area and slope. Glaciers in the Karakoram Mountains had the fastest average flow velocity (0.060 m/d), where the glaciers exhibited the largest average area and average slope. Moreover, glaciers in the Gangdisê Mountains had the slowest velocity (0.022 m/d) and the smallest average glacier area. The glacier flows were the fastest in spring (0.058 m/d), followed by summer (0.050 m/d), autumn (0.041 m/d), and winter (0.040 m/d). In addition, the glacier flows were the maximum in May, being 1.4 times of the annual average velocity. In some areas, such as the Qilian, Altun, Tibetan Interior, Eastern Kunlun, and Western Kunlun mountains, the peak glacier velocities appeared in June and July. The glacier velocity in the HMA region decreased in midsummer and reached the minimum in December when it was 75% of the annual average. These results highlight the role of meltwater in the seasonal variation in glacier flows in late spring and early summer. The seasonal velocity variation of lake-terminating glaciers was similar to that of land-terminating ones, but the former flowed faster. The velocity difference close to the mass balance line between the lake- and land-terminating glaciers was obviously greater in spring than in other seasons. In summer, the difference between the lake- and land-terminating glaciers at a normalized distance of 0.05-0.40 from the terminus was significantly greater than those of other seasons. The velocity difference between the lake- and land-terminating glaciers is closely related to the variable of ice thickness, and also to the frictional force of the terminal base reduced by proglacial lakes. Thus, it can be concluded that in addition to the variation of the glacier thickness and viscosity, the variation of glacier water input also plays a key role in the seasonal variation of glacier velocity.

Key wordsglacier velocity      spatial-temporal variations      High Mountain Asia      synthetic aperture radar offset-tracking      climate change     
Received: 17 January 2023      Published: 30 June 2023
Corresponding Authors: * ZHANG Zhen (E-mail: zhangzhen@aust.edu.cn)
Service
E-mail this article
Add to my bookshelf
Add to citation manager
E-mail Alert
RSS
Articles by authors
ZHANG Zhen
XU Yangyang
LIU Shiyin
DING Jing
ZHAO Jinbiao
Cite this article:

ZHANG Zhen, XU Yangyang, LIU Shiyin, DING Jing, ZHAO Jinbiao. Seasonal variations in glacier velocity in the High Mountain Asia region during 2015-2020. Journal of Arid Land, 2023, 15(6): 637-648.

URL:

http://jal.xjegi.com/10.1007/s40333-023-0016-5     OR     http://jal.xjegi.com/Y2023/V15/I6/637

Fig. 1 Location of the HMA (High Mountain Asia) region and distribution of glaciers. Mountain boundary data are referenced from the following website https://www.mountcryo.org/datasets/. Mts, mountains; n, number of samples.
Fig. 2 Glacier velocities in different mountains for all glaciers (a) and excluding surging glaciers (b)
Mountains Average area (km2) Average velocity (m/d) Uncertainty
(m/d)		 Average slope (°)
IS NS IS NS IS NS
Altun Mts 0.63 0.60 0.055 0.054 0.009 27.235 27.269
Central Himalaya Mts 1.18 1.18 0.051 0.051 0.010 26.353 26.352
Central Tianshan Mts 1.25 0.98 0.048 0.045 0.015 26.615 26.676
Junggar Alatau Mts 0.54 0.54 0.037 0.037 0.017 23.698 23.698
Eastern Himalaya Mts 1.07 1.06 0.049 0.049 0.012 23.569 23.567
Eastern Hindu Kush Mts 0.67 0.63 0.062 0.060 0.009 24.739 24.752
Eastern Kunlun Mts 0.97 0.81 0.046 0.044 0.007 24.162 24.201
Eastern Pamir Mts 1.34 0.90 0.049 0.041 0.011 26.929 26.961
Eastern Tibetan Mts 0.60 0.53 0.041 0.039 0.012 23.628 23.650
Eastern Tianshan Mts 0.55 0.55 0.035 0.035 0.014 27.606 27.605
Gangdisê Mts 0.33 0.33 0.022 0.022 0.005 23.986 23.990
Hengduan Mts 0.62 0.62 0.043 0.043 0.013 23.059 23.059
Karakoram Mts 1.85 1.04 0.077 0.060 0.012 31.277 31.398
Northern&Western Tianshan Mts 0.58 0.54 0.042 0.041 0.016 23.117 23.151
Nyainqêntanglha Mts 0.95 0.95 0.058 0.058 0.013 24.913 24.912
Pamir-Alay Mts 0.59 0.58 0.053 0.052 0.012 25.219 25.225
Qilian Mts 0.60 0.57 0.032 0.031 0.008 26.423 26.45
Tanggula Mts 1.16 0.97 0.035 0.034 0.013 21.361 21.446
Tibetan Interior Mts 1.09 0.99 0.049 0.045 0.006 22.568 22.623
Western Himalaya Mts 0.81 0.79 0.057 0.056 0.011 24.307 24.309
Western Kunlun Mts 1.49 1.13 0.042 0.039 0.007 26.450 26.548
Western Pamir Mts 0.93 0.62 0.057 0.047 0.011 26.649 26.756
HMA 1.02 0.83 0.053 0.049 0.013 25.926 25.956
Table 1 Average glacier area, slope, and velocity of the mountains
Fig. 3 Monthly velocity enhancement factors for all glaciers (a) and excluding surging glaciers (b). The horizontal dashed line in green is a horizontal line at y=1.0, representing the monthly average glacial velocity is equal to the annual average glacial velocity.
Fig. 4 Seasonal velocities of all glaciers (a) and excluding surging glaciers (b). The upper and lower black bars represent a range defined as all values 1.5 times the interquartile range larger (smaller) than the third (first) quartile.
Fig. 5 Regional interannual variations in the velocities of all glaciers (a) and excluding surging glaciers (b)
Fig. 6 Regional seasonal velocities of all glaciers (a) and excluding surging glaciers (b)
Fig. 7 Glacier velocity profiles along centreline for different types of glaciers in different seasons. The median and interquartile ranges are shown in bins of size 0.01. Each glacier's centreline length is used to normalize the distance from its terminus. (a), spring; (b), summer; (c), autumn; (d), winter.
[1]   Armstrong W, Anderson R, Fahnestock M. 2017. Spatial patterns of summer speedup on south central Alaska Glaciers. Geophysical Research Letters, 44(18): 9379-9388.
doi: 10.1002/grl.v44.18
[2]   Brun F, Berthier E, Wagnon P, et al. 2017. A spatially resolved estimate of High Mountain Asia glacier mass balances, 2000-2016. Nature Geoscience, 10(9): 668-673.
[3]   Burgess E, Larsen C, Forster R. 2013. Summer melt regulates winter glacier flow speeds throughout Alaska. Geophysical Research Letters, 40(23): 6160-6164.
doi: 10.1002/grl.v40.23
[4]   Chen F, Zhang M, Guo H, et al. 2021. Annual 30 m dataset for glacial lakes in High Mountain Asia from 2008 to 2017. Earth System Science Data, 13(2): 741-766.
doi: 10.5194/essd-13-741-2021
[5]   Cuffey K, Paterson W. 2010. The Physics of Glaciers, Glaciology (4th ed.). Burlington: Elsevier, 285-398.
[6]   Das S, Sharma M. 2021. Glacier surface velocities in the Jankar Chhu Watershed, western Himalaya, India: Study using Landsat time series data (1992-2020). Remote Sensing Applications: Society and Environment, 24: 100615, doi: 10.1016/j.rsase.2021.100615.
doi: 10.1016/j.rsase.2021.100615
[7]   Dehecq A, Gourmelen N, Gardner A, et al. 2019. Twenty-first century glacier slowdown driven by mass loss in High Mountain Asia. Nature Geoscience, 12(1): 22-27.
doi: 10.1038/s41561-018-0271-9
[8]   Frappé T, Clarke G. 2007. Slow surge of Trapridge Glacier, Yukon Territory, Canada. Journal of Geophysical Research: Earth Surface, 112(F3): F03S32, doi: 10.1029/2006JF000607.
doi: 10.1029/2006JF000607
[9]   Friedl P, Seehaus T, Braun M. 2021. Global time series and temporal mosaics of glacier surface velocities derived from Sentinel-1 data. Earth System Science Data, 13(10): 4653-4675.
doi: 10.5194/essd-13-4653-2021
[10]   Fu Y, Liu Q, Liu G, et al. 2022. Seasonal ice dynamics in the lower ablation zone of Dagongba Glacier, southeastern Tibetan Plateau, from multitemporal UAV images. Journal of Glaciology, 68(270): 636-650.
doi: 10.1017/jog.2021.123
[11]   Guillet G, King O, Lv M, et al. 2022. A regionally resolved inventory of High Mountain Asia surge-type glaciers, derived from a multi-factor remote sensing approach. The Cryosphere, 16(2): 603-623.
doi: 10.5194/tc-16-603-2022
[12]   Herreid S, Truffer M. 2016. Automated detection of unstable glacier flow and a spectrum of speedup behaviour in the Alaska Range. Journal of Geophysical Research: Earth Surface, 121(1): 64-81.
doi: 10.1002/jgrf.v121.1
[13]   Horgan H, Anderson B, Alley R, et al. 2015. Glacier velocity variability due to rain-induced sliding and cavity formation. Earth and Planetary Science Letters, 432: 273-282.
doi: 10.1016/j.epsl.2015.10.016
[14]   Howat I, Box J, Ahn Y, et al. 2010. Seasonal variability in the dynamics of marine-terminating outlet glaciers in Greenland. Journal of Glaciology, 56(198): 601-613.
doi: 10.3189/002214310793146232
[15]   Immerzeel W, Lutz A, Andrade M, et al. 2019. Importance and vulnerability of the world's water towers. Nature, 577(7790): 364-369.
doi: 10.1038/s41586-019-1822-y
[16]   Kraaijenbrink P, Meijer S, Shea J, et al. 2016. Seasonal surface velocities of a Himalayan glacier derived by automated correlation of unmanned aerial vehicle imagery. Annals of Glaciology, 57(71): 103-113.
doi: 10.3189/2016AoG71A072
[17]   Kraaijenbrink P, Bierkens M, Lutz A, et al. 2017. Impact of a global temperature rise of 1.5 degrees Celsius on Asia's glaciers. Nature, 549(7671): 257-260.
doi: 10.1038/nature23878
[18]   Liu L, Jiang L, Sun Y, et al. 2019. Diurnal fluctuations of glacier surface velocity observed with terrestrial radar interferometry at Laohugou No. 12 Glacier, western Qilian Mountains, China. Journal of Glaciology, 65(250): 239-248.
doi: 10.1017/jog.2019.1
[19]   Lüttig C, Neckel N, Humbert A. 2017. A combined approach for filtering ice surface velocity fields derived from remote sensing methods. Remote Sensing, 9(10): 1062, doi: 10.3390/rs9101062.
doi: 10.3390/rs9101062
[20]   Maussion F, Butenko A, Champollion N, et al. 2019. The open global glacier model (OGGM) v1.1. Geoscientific Model Development, 12(3): 909-931.
doi: 10.5194/gmd-12-909-2019
[21]   Nie Y, Pritchard H, Liu Q, et al. 2021. Glacial change and hydrological implications in the Himalaya and Karakoram. Nature Reviews Earth & Environment, 2(2): 91-106.
[22]   Paul F, Bolch T, Kääb A, et al. 2015. The glaciers climate change initiative: Methods for creating glacier area, elevation change and velocity products. Remote Sensing of Environment, 162: 408-426.
doi: 10.1016/j.rse.2013.07.043
[23]   Pritchard H. 2019. Asia's shrinking glaciers protect large populations from drought stress. Nature, 569(7758): 649-654.
doi: 10.1038/s41586-019-1240-1
[24]   Pronk J, Bolch T, King O, et al. 2021. Contrasting surface velocities between lake- and land-terminating glaciers in the Himalayan Region. The Cryosphere, 15(12): 5577-5599.
doi: 10.5194/tc-15-5577-2021
[25]   RGI (Randolph Glacier Inventory). 2017. Randolph Glacier Inventory-Dataset of Global Glacier Outlines, Version 6. Boulder: National Snow and Ice Data Center, 3-16.
[26]   Sam L, Bhardwaj A, Kumar R, et al. 2018. Heterogeneity in topographic control on velocities of Western Himalayan glaciers. Scientific Reports, 8(1): 12843, doi: 10.1038/s41598-018-31310-y.
doi: 10.1038/s41598-018-31310-y pmid: 30150785
[27]   Samsonov S, Tiampo K, Cassotto R. 2021. SAR-derived flow velocity and its link to glacier surface elevation change and mass balance. Remote Sensing of Environment, 258: 112343, doi: 10.1016/j.rse.2021.112343.
doi: 10.1016/j.rse.2021.112343
[28]   Sanchez-Gamez P, Navarro F. 2017. Glacier surface velocity retrieval using D-InSAR and offset tracking techniques applied to ascending and descending passes of Sentinel-1 data for southern Ellesmere Ice Caps, Canadian Arctic. Remote Sensing, 9(5): 442, doi: 10.3390/rs9050442.
doi: 10.3390/rs9050442
[29]   Schaffer N, Copland L, Zdanowicz C. 2017. Ice velocity changes on Penny Ice Cap, Baffin Island, since the 1950s. Journal of Glaciology, 63(240): 716-730.
doi: 10.1017/jog.2017.40
[30]   Schellenberger T, Dunse T, Kääb A, et al. 2015. Surface speed and frontal ablation of Kronebreen and Kongsbreen, NW Svalbard, from SAR offset tracking. The Cryosphere, 9(6): 2339-2355.
doi: 10.5194/tc-9-2339-2015
[31]   Shen C, Jia L, Ren S. 2022. Inter- and intra-annual glacier elevation change in High Mountain Asia region based on ICESat-1&2 Data using elevation-aspect bin analysis method. Remote Sensing, 14(7): 1630, doi: 10.3390/rs14071630.
doi: 10.3390/rs14071630
[32]   Singh D, Thakur P, Naithani B. 2021. Spatio-temporal analysis of glacier surface velocity in Dhauliganga basin using geo-spatial techniques. Environmental Earth Sciences, 80(1): 11, doi: 10.1007/s12665-020-09283-x.
doi: 10.1007/s12665-020-09283-x
[33]   Sun Y, Jiang L, Liu L, et al. 2017. Spatial-temporal characteristics of glacier velocity in the central Karakoram revealed with 1999-2003 Landsat-7 ETM+ pan images. Remote Sensing, 9(10): 1064, doi: 10.3390/rs9101064.
doi: 10.3390/rs9101064
[34]   Usman M, Furuya M. 2018. Interannual modulation of seasonal glacial velocity variations in the Eastern Karakoram detected by ALOS-1/2 data. Journal of Glaciology, 64(245): 465-476.
doi: 10.1017/jog.2018.39
[35]   Wegnüller U, Werner C, Strozzi T, et al. 2016. Sentinel-1 support in the GAMMA software. Procedia Computer Science, 100: 1305-1312.
doi: 10.1016/j.procs.2016.09.246
[36]   Wendleder A, Friedl P, Mayer C. 2018. Impacts of climate and supraglacial lakes on the surface velocity of Baltoro glacier from 1992 to 2017. Remote Sensing, 10(11): 1681, doi: 10.3390/rs10111681.
doi: 10.3390/rs10111681
[37]   Wu K, Liu S, Zhu Y, et al. 2020. Dynamics of glacier surface velocity and ice thickness for maritime glaciers in the southeastern Tibetan Plateau. Journal of Hydrology, 590: 125527, doi: 10.1016/j.jhydrol.2020.125527.
doi: 10.1016/j.jhydrol.2020.125527
[38]   Yan S, Li Y, Li Z, et al. 2018. An insight into the surface velocity of Inylchek Glacier and its effect on Lake Merzbacher during 2006-2016 with Landsat time-series imagery. Environmental Earth Sciences, 77: 773, doi: 10.1007/s12665-018-7964-7.
doi: 10.1007/s12665-018-7964-7
[39]   Yan X, Ma J, Ma X, et al. 2021. Hydrothermal combination and geometry control the spatial and temporal rhythm of glacier flow. Science of the Total Environment, 760: 144315, doi: 10.1016/j.scitotenv.2020.144315.
doi: 10.1016/j.scitotenv.2020.144315
[40]   Yang R, Hock R, Kang S, et al. 2022. Glacier surface speed variations on the Kenai Peninsula, Alaska, 2014-2019. Journal of Geophysical Research: Earth Surface, 127(3): 1-22.
[41]   Yang W, Zhao C, Westoby M, et al. 2020. Seasonal dynamics of a temperate Tibetan glacier revealed by high-resolution UAV photogrammetry and in situ measurements. Remote Sensing, 12(15): 2389, doi: 10.3390/rs12152389.
doi: 10.3390/rs12152389
[42]   Yao T, Thompson L, Yang W, et al. 2012. Different glacier status with atmospheric circulations in Tibetan Plateau and surroundings. Nature Climate Change, 2(9): 663-667.
doi: 10.1038/nclimate1580
[43]   Zhang J, Jia L, Menenti M, et al. 2020. Interannual and seasonal variability of glacier surface velocity in the Parlung Zangbo Basin, Tibetan Plateau. Remote Sensing, 13(1): 80, doi: 10.3390/rs13010080.
doi: 10.3390/rs13010080
[44]   Zhang Z, Gu Z, Hu K, et al. 2022a. Spatial variability between glacier mass balance and environmental factors in the High Mountain Asia. Journal of Arid Land, 14(4): 441-454.
doi: 10.1007/s40333-017-0014-z
[45]   Zhang Z, Tao P, Liu S, et al. 2022b. What controls the surging of Karayaylak glacier in eastern Pamir?. New insights from remote sensing data. Journal of Hydrology, 607: 127577, doi: 10.1016/j.jhydrol.2022.127577.
doi: 10.1016/j.jhydrol.2022.127577
[1] CHEN Zhuo, SHAO Minghao, HU Zihao, GAO Xin, LEI Jiaqiang. Potential distribution of Haloxylon ammodendron in Central Asia under climate change[J]. Journal of Arid Land, 2024, 16(9): 1255-1269.
[2] SUN Chao, BAI Xuelian, WANG Xinping, ZHAO Wenzhi, WEI Lemin. Response of vegetation variation to climate change and human activities in the Shiyang River Basin of China during 2001-2022[J]. Journal of Arid Land, 2024, 16(8): 1044-1061.
[3] YAN Yujie, CHENG Yiben, XIN Zhiming, ZHOU Junyu, ZHOU Mengyao, WANG Xiaoyu. Impacts of climate change and human activities on vegetation dynamics on the Mongolian Plateau, East Asia from 2000 to 2023[J]. Journal of Arid Land, 2024, 16(8): 1062-1079.
[4] YANG Jianhua, LI Yaqian, ZHOU Lei, ZHANG Zhenqing, ZHOU Hongkui, WU Jianjun. Effects of temperature and precipitation on drought trends in Xinjiang, China[J]. Journal of Arid Land, 2024, 16(8): 1098-1117.
[5] HAN Qifei, XU Wei, LI Chaofan. Effects of nitrogen deposition on the carbon budget and water stress in Central Asia under climate change[J]. Journal of Arid Land, 2024, 16(8): 1118-1129.
[6] WANG Tongxia, CHEN Fulong, LONG Aihua, ZHANG Zhengyong, HE Chaofei, LYU Tingbo, LIU Bo, HUANG Yanhao. Glacier area change and its impact on runoff in the Manas River Basin, Northwest China from 2000 to 2020[J]. Journal of Arid Land, 2024, 16(7): 877-894.
[7] DU Lan, TIAN Shengchuan, ZHAO Nan, ZHANG Bin, MU Xiaohan, TANG Lisong, ZHENG Xinjun, LI Yan. Climate and topography regulate the spatial pattern of soil salinization and its effects on shrub community structure in Northwest China[J]. Journal of Arid Land, 2024, 16(7): 925-942.
[8] Haq S MARIFATUL, Darwish MOHAMMED, Waheed MUHAMMAD, Kumar MANOJ, Siddiqui H MANZER, Bussmann W RAINER. Predicting potential invasion risks of Leucaena leucocephala (Lam.) de Wit in the arid area of Saudi Arabia[J]. Journal of Arid Land, 2024, 16(7): 983-999.
[9] Seyed Morteza MOUSAVI, Hossein BABAZADEH, Mahdi SARAI-TABRIZI, Amir KHOSROJERDI. Assessment of rehabilitation strategies for lakes affected by anthropogenic and climatic changes: A case study of the Urmia Lake, Iran[J]. Journal of Arid Land, 2024, 16(6): 752-767.
[10] LI Chuanhua, ZHANG Liang, WANG Hongjie, PENG Lixiao, YIN Peng, MIAO Peidong. Influence of vapor pressure deficit on vegetation growth in China[J]. Journal of Arid Land, 2024, 16(6): 779-797.
[11] LU Haitian, ZHAO Ruifeng, ZHAO Liu, LIU Jiaxin, LYU Binyang, YANG Xinyue. Impact of climate change and human activities on the spatiotemporal dynamics of surface water area in Gansu Province, China[J]. Journal of Arid Land, 2024, 16(6): 798-815.
[12] YANG Zhiwei, CHEN Rensheng, LIU Zhangwen, ZHAO Yanni, LIU Yiwen, WU Wentong. Spatiotemporal variability of rain-on-snow events in the arid region of Northwest China[J]. Journal of Arid Land, 2024, 16(4): 483-499.
[13] ZHANG Mingyu, CAO Yu, ZHANG Zhengyong, ZHANG Xueying, LIU Lin, CHEN Hongjin, GAO Yu, YU Fengchen, LIU Xinyi. Spatiotemporal variation of land surface temperature and its driving factors in Xinjiang, China[J]. Journal of Arid Land, 2024, 16(3): 373-395.
[14] WANG Baoliang, WANG Hongxiang, JIAO Xuyang, HUANG Lintong, CHEN Hao, GUO Wenxian. Runoff change in the Yellow River Basin of China from 1960 to 2020 and its driving factors[J]. Journal of Arid Land, 2024, 16(2): 168-194.
[15] LIU Xinyu, LI Xuemei, ZHANG Zhengrong, ZHAO Kaixin, LI Lanhai. A CMIP6-based assessment of regional climate change in the Chinese Tianshan Mountains[J]. Journal of Arid Land, 2024, 16(2): 195-219.