Risk Assessment of Debris Flows Along the Karakoram Highway (Kashgar-Khunjerab Section) in the Context of Climate Change

Yamei Li; Qiang Zou; Jiansheng Hao; Lijun Su

doi:10.1007/s13753-023-00501-1

International Journal of Disaster Risk Science ›› 2023, Vol. 14 ›› Issue (4) : 586 -599. DOI: 10.1007/s13753-023-00501-1

Article

Risk Assessment of Debris Flows Along the Karakoram Highway (Kashgar-Khunjerab Section) in the Context of Climate Change

Yamei Li ¹
, Qiang Zou ²^,³
, Jiansheng Hao ⁴
, Lijun Su ²^,³^,⁵^,^d

Author information +

History +

PDF

Abstract

The Karakoram highway (KKH) is renowned for its complex natural environment and geological conditions. The climate changes drastically and directly influences the frequency and magnitude of debris flows in this region, resulting in significant casualties and economic losses. However, the risk assessment of debris flows along the KKH in the context of climate change has been rarely explored. Therefore, in this study we used the debris flow data, historical meteorological data and future climate prediction data to assess the debris flow risk of the study region during the baseline period (2009–2018), 2025s (2021–2030), 2035s (2031–2040) and 2045s (2041–2050) under the Representative Concentration Pathway 8.5 scenario. The results show that the risk of debris flows increases with climate change, with the highest risk level in the 2025s. Among different parts of this highway, the upper reaches of the Ghez River and the second half of Tashkorgan-Khunjerab are the sections with the highest risk. These findings are helpful for debris flow prevention and can offer coping strategies for the existing line of the KKH. They also provide some reference for the renovation, improvement, operation, and maintenance of the KKH.

Keywords

Climate change / Debris flows / Karakoram highway / Risk assessment

Cite this article

Download citation ▾

Yamei Li, Qiang Zou, Jiansheng Hao, Lijun Su. Risk Assessment of Debris Flows Along the Karakoram Highway (Kashgar-Khunjerab Section) in the Context of Climate Change. International Journal of Disaster Risk Science, 2023, 14(4): 586-599 DOI:10.1007/s13753-023-00501-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Aizen V, Aizen E. Hydrological cycles on the north and south peripheries of mountain-glacial basins of Central Asia. Hydrological Processes, 1997, 11(5): 451-469

[2]	Ali S, Haider R, Abbas W, Basharat M, Reicherter K. Empirical assessment of rockfall and debris flow risk along the Karakoram highway, Pakistan. Natural Hazards, 2021, 106(6): 2437-2460

[3]	Beniston M. Mountain climates and climatic change: An overview of processes focusing on the European Alps. Pure Applied Geophysics, 2005, 162: 1587-1606

[4]	Chiarle M, Iannotti S, Mortara G, Deline P. Recent debris flow occurrences associated with glaciers in the Alps. Global and Planetary Change, 2007, 56(1/2): 123-136

[5]	Cui P, Chen XQ, Waqng YY, Hu KH, Li Y. Jakob M, Hungr O. Jiangjia Ravine debris flows in south-western China. Debris-flow hazards and related phenomena, 2005, Berlin: Springer 565-594

[6]	Dai YJ. A China soil characteristics dataset, 2019, Lanzhou: National Cryosphere Desert Data Center

[7]	Derbyshire E. Glacier regime and glacial sediment facies: A hypothetical framework for the Qinghai-Xizang Plateau. Proceedings of the symposium on Qinghai-Xizang (Tibet) plateau, 1981, Beijing: Science Press 1649-1656.

[8]	Donat MG, Lowry AL, Alexander LV, O’Gorman PA, Maher N. More extreme precipitation in the world’s dry and wet regions. Nature Climate Change, 2016, 6: 508-513

[9]	Evans SG, Clague JJ. Recent climatic change and catastrophic geomorphic processes in mountain environments. Geomorphology, 1994, 10(1–4): 107-128

[10]	Fuchs MC, Gloaguen R, Krbetschek M, Szulc A. Rates of river incision across the main tectonic units of the Pamir identified using optically stimulated luminescence dating of fluvial terraces. Geomorphology, 2014, 216(1): 79-92

[11]	Ge YG, Su FH, Chen XQ, Zhang JQ. Destructions on the Karakoram highway (KKH) from Sost to Khunjerab induced by geo-hazards and prevention. Applied Mechanics and Materials, 2015, 744–746: 1234-1243

[12]	Han, H., X.L. Guo, and H. Yu. 2016. Variable selection using mean decrease accuracy and mean decrease Gini based on random forest. In Proceedings of the 2016 7th IEEE international conference on software engineering and service science (ICSESS), 26–28, Aug 2016, Beijing, China.

[13]	Hao XM, Chen YN, Xu CC, Li WH. Impacts of climate change and human activities on the surface runoff in the Tarim River basin over the last fifty years. Water Resources Management, 2008, 2(9): 1159-1171

[14]	Hay LE, Wilby RL, Leavesley GH. A comparison of delta change and downscaled GCM scenarios for three mountain basins in the United States. Journal of the American Water Resources Association, 2000, 36(2): 387-397

[15]	He P, Wang Q, Ding KH, Wang M, Qiao XJ, Li J, Wen YM, Xu CJ, Yang SM, Zou R. Source model of the 2015 Mw 6.4 Pishan earthquake constrained by interferometric synthetic aperture radar and GPS: Insight into blind rupture in the western Kunlun Shan. Geophysical Research Letters, 2016, 43: 1511-1519

[16]	He, J., K. Yang, W.J. Tang, H. Lu, J. Qin, Y.Y. Chen, and X. Li. 2020. The first high-resolution meteorological forcing dataset for land process studies over China. Scientific Data 7: Article 25.

[17]	Huss M, Hock R. Global-scale hydrological response to future glacier mass loss. Nature Climate Change, 2018, 8: 135-140

[18]

IPCC (Intergovernmental Panel on Climate Change). 2013. Summary for policymakers. In Climate change 2013: The physical science basis. Contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change, ed. T.F. Stocker, D.H. Qin, G.K. Plattner, M.M.B. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, et al. Cambridge: Cambridge University Press.

[19]

IPCC (Intergovernmental Panel on Climate Change). 2021. Summary for policymakers. In Climate change 2021: The physical science basis. Contribution of working group I to the sixth assessment report of the intergovernmental panel on climate change, ed. V. Masson-Delmotte, P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, et al. Cambridge: Cambridge University Press.

[20]	Iverson RM. Debris flows: Behaviour and hazard assessment. Geology Today, 2014, 30(1): 15-20

[21]	Larsson S. Geomorphological effects on the slopes of Longyear Valley, Spitsbergen, after a heavy rainstorm in July 1972. Geografiska Annaler, 1982, 64A(3/4): 105-125

[22]	Li MW. Regularity of strong earthquakes in Pamir-West Kunlun seismic zone. Inland Earthquake, 1994, 8(2): 134-140 in Chinese

[23]	Li T, Chen J, Fang LH, Chen ZX, Thompson JA, Jia CZ. The 2015 Mw 6.4 Pishan earthquake: Seismic hazards of an active blind wedge thrust system at the western Kunlun range front, northwest Tibetan Plateau. Seismological Research Letters, 2016, 87(3): 601-608

[24]	Li D, Yang K, Tang WJ, Li X, Zhou X, Guo DL. Characterizing precipitation in high altitudes of the western Tibetan Plateau with a focus on major glacier areas. International Journal of Climatology, 2020, 40: 5114-5127

[25]	Liao LP, Zhu YY, Zou DHS, Yang ZQ, Muhammad W, Chen JD, Wang Y, Ye CY. Key point of bridge damage caused by glacial debris flows along international Karakorum highway, Pakistan. Applied Mechanics and Materials, 2012, 256–259: 2713-2723

[26]	Liu WJ. FVC dataset of remote sensing for ecological assets assessment in Qinghai-Tibet Plateau, 2019, Beijing: National Tibetan Plateau/Third Pole Environment Data Center

[27]	Ma, J. 2015. Seismic catalogue of east China (2300 BC–2500 AD). Lanzhou, China: A Big Earth Data Platform for Three Poles, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences.

[28]	Ouyang, C.J., Z.W. Wang, H.C. An, X.R. Liu, and D.P. Wang. 2019. An example of a hazard and risk assessment for debris flows − A case study of Niwan Gully, Wudu, China. Engineering Geology 263: Article 105351.

[29]	Owen LA, Benn DI. Equilibrium-line altitudes of the last glacial maximum for the Himalaya and Tibet: An assessment and evaluation of results. Quaternary International, 2005, 138–139: 55-78

[30]	Owen LA, Derbyshire E. The Karakoram glacial depositional system. Zeitschrift für Geomorphologie, 1989, 76: 33-74.

[31]	Pan XD, Zhang L. Future climate projection over Northwest China based on RegCM4.6 (2007–2099), 2019, Beijing: National Tibetan Plateau/Third Pole Environment Data Center

[32]	Pan XD, Zhang L, Huang CL. Future climate projection in Northwest China with RegCM4.6. Earth and Space Science, 2020, 7(2): 1-18

[33]	Pei, Y.Q., H.J. Qiu, D.D. Yang, Z.J. Liu, S.Y. Ma, J.Y. Li, M.M. Cao, and W. Wufuer. 2023. Increasing landslide activity in the Taxkorgan River Basin (eastern Pamirs Plateau, China) driven by climate change. CATENA 223: Article 106911.

[34]	Peltzer G, Tapponnier P, Armijo R. Magnitude of late quaternary left-lateral displacement along the north edge of Tibet. Science, 1989, 246: 1285-1289

[35]	Qing F, Zhao Y, Meng XM, Su XJ, Qi TJ, Yue DX. Application of machine learning to debris flow susceptibility mapping along the China-Pakistan Karakoram Highway. Remote Sensing, 2020, 12(18): 1-22

[36]	Rahardjo H, Ong TH, Rezaur RB, Leong EC. Factors controlling instability of homogeneous soil slopes under rainfall. Journal of Geotechnical and Geoenvironmental Engineering, 2007, 133(12): 1532-1543

[37]	Ramanathan R. A note on the use of the analytic hierarchy process for environmental impact assessment. Journal of Environmental Management, 2001, 63(1): 27-35

[38]	Ramirez-Villegas, J., and A. Jarvis. 2010. Downscaling global circulation model outputs: The delta method decision and policy analysis working paper No.1. International Center for Tropical Agriculture, CIAT, Cali, Colombia.

[39]	Ren Z, Su FG, Xu BQ, Xie Y, Kan BY. A coupled glacier-hydrology model and its application in eastern Pamir. Journal of Geophysical Research-Atmosphere, 2018, 123(13): 692-713.

[40]	Sarr MA, Seidou O, Tramblay Y, Adlouni SE. Comparison of downscaling methods for mean and extreme precipitation in Senegal. Journal of Hydrology: Regional Studies, 2015, 4: 369-385.

[41]	Schoenbohm LM, Chen J, Stutz J, Sobel ER, Thiede RC, Kirby B, Strecker MR. Glacial morphology in the Chinese Pamir: Connections among climate, erosion, topography, lithology and exhumation. Geomorphology, 2014, 221: 1-17

[42]	Schwalm CR, Glendon S, Duffy PB. RCP8.5 tracks cumulative CO2 emissions. Proceedings of the National Academy of Sciences, 2020, 117(33): 19656-19657

[43]	Shroder JF. Slope failure and denudation in the western Himalaya. Geomorphology, 1998, 26: 81-105

[44]	Sobel ER, Dumitru TA. Thrusting and exhumation around the margins of the western Tarim Basin during the India-Asia collision. Journal of Geophysical Research: Solid Earth, 1997, 102: 5043-5063

[45]	Staffler H, Pollinger R, Zischg A, Mani P. Spatial variability and potential impacts of climate change on flood and debris flow hazard zone mapping and implications for risk management. Natural Hazards and Earth System Sciences, 2008, 8: 539-558

[46]	Stoffel M, Mendlik T, Schneuwly-Bollschweiler M, Gobiet A. Possible impacts of climate change on debris-flow activity in the Swiss Alps. Climatic Change, 2014, 122: 141-155

[47]	Sun JQ, Chen XM. Engineering geology, 2007, Wuhan: Wuhan University of Technology Press

[48]	Sun H, Su FG, Huang JH, Yao TD, Luo Y, Chen DL. Contrasting precipitation gradient characteristics between westerlies and monsoon dominated upstream river basins in the Third Pole. Chinese Science Bulletin, 2020, 65(1): 91-104

[49]	Tibshirani R. Bias, variance and prediction error for classification rules. Monographs of the Society for Research in Child Development, 1996, 79: 1-17.

[50]	Varnes DJ. IAEG commission on landslides and other mass-movements. Landslide hazard zonation: A review of principles and practice, 1984, Paris: The UNESCO Press

[51]	Wang JR. An analysis of the harm and genesis of glacial debris flows along the China-Pakistan Highway from Kashi to Tashikuergan. Journal of Glaciology and Geocryology, 1987, 9(1): 87-94 in Chinese

[52]	Wang, J. 2020. Earthquake catalogue with M≥5 in Pan-Third Pole since 1960. Beijing: National Tibetan Plateau/Third Pole Environment Data Center.

[53]	Wedley WC. Combining qualitative and quantitative factors – An analytic hierarchy approach. Socio-Economic Planning Sciences, 1990, 24(1): 57-64

[54]	Westra S, Fowler HJ, Evans JP, Alexander LV, Berg P, Johnson F, Kendon EJ, Lenderink G, Roberts NM. Future changes to the intensity and frequency of short-duration extreme rainfall. Reviews of Geophysics, 2014, 52(3): 522-555

[55]	Wolpert DH, Macready WG. An efficient method to estimate bagging’s generalization error. Machine Learning, 1999, 35(1): 41-55

[56]	Wright TJ, Parsons B, England PC, Fielding EJ. InSAR observations of low slip rates on the major faults of western Tibet. Science, 2004, 305: 236-239

[57]	Xu WX, Yang WS, Sun JJ, Zhang JG, Yu DH. Statistical regression analysis of empirical relationships of epicentral intensity, magnitude and focal depth. Journal of Natural Disasters, 2016, 25(2): 139-145 in Chinese

[58]	Xu HL, Zhou B, Song YD. Impacts of climate change on headstream runoff in the Tarim River Basin. Hydrology Research, 2011, 42(1): 20-29

[59]	Yang, K., and J. He. 2019. China meteorological forcing dataset (1979–2018). Lanzhou: A Big Earth Data Platform for Three Poles, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences.

[60]	Yao, J.Q., Y.N. Chen, X.F. Guan, Y. Zhao, J. Chen, and W.Y. Mao. 2022. Recent climate and hydrological changes in a mountain-basin system in Xinjiang, China. Earth-Science Reviews 226: Article 103957.

[61]	Yao TD, Thompson L, Yang W, Yu WS, Gao Y, Guo XJ, Yang XX, Duan KQ Different glacier status with atmospheric circulations in Tibetan Plateau and surroundings. Nature Climate Change, 2012, 2: 663-667

[62]	Yao TD, Wang YQ, Liu SY, Pu JC, Shen YP, Lu AX. Recent glacial retreat in High Asia in China and its impact on water resource in Northwest China. Science in China: Earth Sciences, 2004, 47(12): 1065-1075.

[63]	Zhang Z, Liu SY, Wei JF, Xu JL, Guo WQ, Bao WJ, Jiang ZL. Mass change of glaciers in Muztag Ata-Kongur Tagh, Eastern Pamir, China from 1971/76 to 2013/14 as derived from remote sensing data. PLoS ONE, 2016, 11(1): 1-18

[64]	Zimmermann M, Haeberli W. Climatic change and debris flow activity in high mountain areas – A case study in the Swiss Alps. CATENA Supplement, 1992, 22: 59-72.

[65]	Zou Q, Guo XJ, Luo Y, Jiang YJ, Cui P, Su LJ, Ou GQ, Pan HL, Liu WM. Spatial pattern and response of landslide and debris flow risks in China-Pakistan Economic Corridor. Bulletin of Chinese Academy of Sciences, 2021, 36(2): 160-169.