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Geocarto International Volume 37, 2022 - Issue 22
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Original Articles

Analysis of spatiotemporal variation in the snow cover in Western Hindukush-Himalaya region

Abdul Haseeb Azizia Department of Civil Engineering, Graduate School of Engineering, Nihon University, Koriyama, JapanCorrespondence[email protected]
&
Fazlullah Akhtarb Center for Development Research (ZEF), University of Bonn, Bonn, Germany
Pages 6602-6624 | Received 06 Apr 2021, Accepted 28 May 2021, Published online: 21 Jun 2021

References

  • Ahmad S, Israr M, Liu S, Hayat H, Gul J, Wajid S, Ashraf M, Baig SU, Tahir AA. 2020. Spatio-temporal trends in snow extent and their linkage to hydro-climatological and topographical factors in the Chitral River Basin (Hindukush, Pakistan). Geocarto Int. 35(7):711–724.
  • Akhtar F, Awan UK, Tischbein B, Liaqat UW. 2017. A phenology based geo-informatics approach to map land use and land cover (2003–2013) by spatial segregation of large heterogenic river basins. Appl Geogr. 88:48–61.
  • Akhtar F, Shah U. 2020. Emerging water scarcity issues and challenges in Afghanistan. In: Water issues in Himalayan South Asia. Singapore: Springer; p. 1–28.
  • Ali S, Cheema MJM, Waqas MM, Waseem M, Awan UK, Khaliq T. 2020. Changes in snow cover dynamics over the Indus basin: evidences from 2008 to 2018 MODIS NDSI trends analysis. Remote Sens. 12(17):2782.
  • Anjum MN, Ding Y, Shangguan D, Liu J, Ahmad I, Ijaz MW, Khan MI. 2019. Quantification of spatial temporal variability of snow cover and hydro-climatic variables based on multi-source remote sensing data in the Swat watershed, Hindukush Mountains. Meteorol Atmos Phys. 131(3):467–486.
  • Archer DR, Fowler HJ. 2004. Spatial and temporal variations in precipitation in the Upper Indus Basin, global teleconnections and hydrological implications. Hydrol Earth Syst Sci. 8(1):47–61.
  • Azizi AH, Asaoka Y. 2019. Estimating spatial and temporal snow distribution using numerical model and satellite remote sensing in the western Hindukush-Himalaya region. J JSCE Ser G. 75(5):I_125–I_134.
  • Azizi AH, Asaoka Y. 2020a. Assessment of the impact of climate change on snow distribution and river flows in a snow-dominated mountainous watershed in the western Hindukush–Himalaya, Afghanistan. Hydrology. 7(4):74.
  • Azizi AH, Asaoka Y. 2020b. Incorporating snow model and snowmelt runoff model for streamflow simulation in a snow-dominated mountainous basin in the western Hindukush-Himalaya region. Hydrol Res Lett. 14(1):34–40.
  • Barman S, Bhattacharjya RK. 2015. Change in snow cover area of Brahmaputra river basin and its sensitivity to temperature. Environ Syst Res. 4(1):16.
  • Barnett TP, Adam JC, Lettenmaier DP. 2005. Potential impacts of a warming climate on water availability in snow-dominated regions. Nature. 438:303–309.
  • Bibi S, Wang L, Li X, Zhou J, Chen D, Yao T. 2018. Climatic and associated cryospheric, biospheric, and hydrological changes on the Tibetan Plateau: a review. Int J Climatol. 38:e1–e17.
  • Bookhagen B, Burbank DW. 2010. Toward a complete Himalayan hydrological budget: spatiotemporal distribution of snowmelt and rainfall and their impact on river discharge. J Geophys Res. 115(F3). DOI:10.1029/2009JF001426
  • Chaponnière A, Maisongrande P, Duchemin B, Hanich L, Boulet G, Escadafal R, Elouaddat S. 2005. A combined high and low spatial resolution approach for mapping snow covered areas in the Atlas Mountains. Int J Remote Sens. 26(13):2755–2777.
  • David R, Brekke L, Werner K, Wood A, White AK. 2013. Short-term water management decisions: user needs for improved climate, weather, and hydrologic information. U.S. Army Corps of Engineers Bureau of Reclamation National Oceanic and Atmospheric Administration Tech. Rep CWTS.
  • Deines JM, Kendall AD, Hyndman DW. 2017. Annual irrigation dynamics in the U.S. northern high plains derived from landsat satellite data. Geophys Res Lett. 44(18):9350–9360.
  • Delgadillo-Herrera M, Arreola-Esquivel M, Toxqui-Quitl C, Padilla-Vivanco A. 2019. Normalized difference indices in Landsat 5 TM satellite data. In: Current Developments in Lens Design and Optical Engineering XX. Vol. 11104. International Society for Optics and Photonics. p. 111040W.
  • FAO. 2012. AQUASTAT Country Profile –Afghanistan. Rome (Italy): Food and Agriculture Organization of the United Nations (FAO).
  • Fayaz N, Vazifedoust M, Araghinejad S. 2013. Monitoring of snow cover variation using MODIS snow product. Int Archiv Photogramm Remote Sens Spatial Inf Sci. 1:W3.
  • Gafurov A, Bárdossy A. 2009. Cloud removal methodology from MODIS snow cover product. Hydrol Earth Syst Sci. 13(7):1361–1373.
  • Gilbert RO. 1987. Statistical methods for environmental pollution monitoring. New York: John Wiley & Sons.
  • Gurung D, Kulkarni A, Giriraj A, Aung K, Shrestha B, Srinivasan J. 2011. Changes in seasonal snow cover in Hindu Kush-Himalayan region. Cryosphere Discuss. 5:755–777.
  • Gurung DR, Giriraj A, Aung KS, Shrestha BR, Kulkarni AV. 2011. Snow-cover mapping and monitoring in the Hindu Kush-Himalayas. International Centre for Integrated Mountain Development (ICIMOD).
  • Gurung DR, Maharjan SB, Shrestha AB, Shrestha MS, Bajracharya SR, Murthy M. 2017. Climate and topographic controls on snow cover dynamics in the Hindu Kush Himalaya. Int J Climatol. 37(10):3873–3882.
  • Hall DK, Riggs GA, Salomonson VV, DiGirolamo NE, Bayr KJ. 2002. MODIS snow-cover products. Remote Sens Environ. 83(1-2):181–194.
  • Hinckley ELS, Ebel BA, Barnes RT, Anderson RS, Williams MW, Anderson SP. 2014. Aspect control of water movement on hillslopes near the rain–snow transition of the Colorado Front Range. Hydrologic Process. 28(1):74–85.
  • Hirsch RM, Slack JR. 1984. A nonparametric trend test for seasonal data with serial dependence. Water Resour Res. 20(6):727–732.
  • Hopkinson C, Pomeroy J, Debeer C, Ellis C, Anderson A. 2012. Relationships between snowpack depth and primary LiDAR point cloud derivatives in a mountainous environment. Remote Sens Hydrol. 352:354–358. https://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=27917455
  • Immerzeel WW, Van Beek LP, Bierkens MF. 2010. Climate change will affect the Asian water towers. Science. 328(5984):1382–1385.
  • Immerzeel WW, Droogers P, de Jong SM, Bierkens MFP. 2009. Large-scale monitoring of snow cover and runoff simulation in Himalayan river basins using remote sensing. Remote Sens Environ. 113(1):40–49.
  • Jain SK, Goswami A, Saraf AK. 2009. Role of elevation and aspect in snow distribution in Western Himalaya. Water Resour Manage. 23(1):71–83.
  • Kour R, Patel N, Krishna AP. 2016a. Assessment of temporal dynamics of snow cover and its validation with hydro-meteorological data in parts of Chenab Basin, western Himalayas. Sci China Earth Sci. 59(5):1081–1094.
  • Kour R, Patel N, Krishna AP. 2016b. Effects of terrain attributes on snow-cover dynamics in parts of Chenab basin, western Himalayas. Hydrol Sci J. 61:1861–1876.
  • Lee S, Klein AG, Over TM. 2005. A comparison of MODIS and NOHRSC snow‐cover products for simulating streamflow using the Snowmelt Runoff Model. Hydrol Process. 19(15):2951–2972.
  • Liang T, Huang X, Wu C, Liu X, Li W, Guo Z, Ren J. 2008. An application of MODIS data to snow cover monitoring in a pastoral area: a case study in Northern Xinjiang, China. Remote Sens Environ. 112(4):1514–1526.
  • Lopez P, Sirguey P, Arnaud Y, Pouyaud B, Chevallier P. 2008. Snow cover monitoring in the Northern Patagonia Icefield using MODIS satellite images (2000–2006). Global Planetary Chang. 61(3-4):103–116.
  • Mann HB. 1945. Nonparametric tests against trend. Econometrica. 13(3):245–259.
  • Marofi S, Tabari H, Abyaneh HZ. 2011. Predicting spatial distribution of snow water equivalent using multivariate non-linear regression and computational intelligence methods. Water Resour Manage. 25(5):1417–1435.
  • Maurer EP, Rhoads JD, Dubayah RO, Lettenmaier DP. 2003. Evaluation of the snow‐covered area data product from MODIS. Hydrol Process. 17(1):59–71.
  • McNamara JP, Chandler D, Seyfried M, Achet S. 2005. Soil moisture states, lateral flow, and streamflow generation in a semi-arid, snowmelt-driven catchment. Hydrol Process. 19(20):4023–4038.
  • Negi H, Jassar H, Saravana G, Snehmani NT, Ganju A. 2013. Snow-cover characteristics using Hyperion data for the Himalayan region. Int J Remote Sens. 34:2140–2161.
  • Parajka J, Pepe M, Rampini A, Rossi S, Blöschl G. 2010. A regional snow-line method for estimating snow cover from MODIS during cloud cover. J Hydrol. 381(3-4):203–212.
  • Pellicciotti F, Bauder A, Parola M. 2010. Effect of glaciers on streamflow trends in the Swiss Alps. Water Resour Res. 46(10). DOI:10.1029/2009WR009039
  • Pellicciotti F, Buergi C, Immerzeel WW, Konz M, Shrestha AB. 2012. Challenges and uncertainties in hydrological modeling of remote Hindu Kush–Karakoram–Himalayan (HKH) basins: suggestions for calibration strategies. Mountain Res Dev. 32(1):39–50.
  • Pomeroy J. 2007. Cold regions hydrology, snow, and PUB. Predictions in ungauged basins: PUB kick-off. Proceedings of the PUB Kick-off meeting, Brasilia; 20–22 November 2002; Vol. 309. IAHS Publ. p. 85–91.
  • Pu Z, Xu L, Salomonson VV. 2007. MODIS/Terra observed seasonal variations of snow cover over the Tibetan Plateau. Geophys Res Lett. 34(6). DOI:10.1029/2007GL029262
  • Salomonson VV, Appel I. 2004. Estimating fractional snow cover from MODIS using the normalized difference snow index. Remote Sens Environ. 89(3):351–360.
  • Sen PK. 1968. Estimates of the regression coefficient based on Kendall's tau. J Am Stat Assoc. 63(324):1379–1389.
  • Shafiq M, Ahmed P, Islam Z, Joshi PK, Bhat WA. 2019. Snow cover area change and its relations with climatic variability in Kashmir Himalayas, India. Geocarto Int. 34(6):688–702.
  • Sharma SS, Ganju A. 2000. Complexities of avalanche forecasting in Western Himalaya – an overview. Cold Reg Sci Technol. 31(2):95–102.
  • She J, Zhang Y, Li X, Feng X. 2015. Spatial and temporal characteristics of snow cover in the Tizinafu watershed of the Western Kunlun Mountains. Remote Sens. 7(4):3426–3445.
  • Shukla S, Kansal ML, Jain SK. 2017. Snow cover area variability assessment in the upper part of the Satluj river basin in India. Geocarto Int. 32(11):1285–1306.
  • Singh SK, Rathore BP, Bahuguna IM, Ajai. 2014. Snow cover variability in the Himalayan–Tibetan region. Int J Climatol. 34:446–452.
  • Song L, Wu R. 2019. Intraseasonal snow cover variations over western Siberia and associated atmospheric processes. J Geophys Res Atmos. 124(16):8994–9010.
  • Stillinger T, Roberts DA, Collar NM, Dozier J. 2019. Cloud masking for Landsat 8 and MODIS Terra over snow-covered terrain: error analysis and spectral similarity between snow and cloud. Water Resour Res. 55:6169–6184.
  • Tachikawa T, Kaku M, Iwasaki A, Gesch DB, Oimoen MJ, Zhang Z, Danielson JJ, Krieger T, Curtis B, Haase J, et al. 2011. ASTER Global Digital Elevation Model Version 2 – summary of validation results. Report.
  • Tahir AA, Adamowski JF, Chevallier P, Haq AU, Terzago S. 2016. Comparative assessment of spatiotemporal snow cover changes and hydrological behavior of the Gilgit, Astore and Hunza River basins (Hindukush–Karakoram–Himalaya region, Pakistan). Meteorol Atmos Phys. 128(6):793–811.
  • Tahir AA, Chevallier P, Arnaud Y, Ahmad B. 2011. Snow cover dynamics and hydrological regime of the Hunza River basin, Karakoram Range, Northern Pakistan. Hydrol Earth Syst Sci. 15(7):2275–2274.
  • Tahir AA, Chevallier P, Arnaud Y, Ashraf M, Bhatti MT. 2015. Snow cover trend and hydrological characteristics of the Astore River basin (Western Himalayas) and its comparison to the Hunza basin (Karakoram region). Sci Total Environ. 505:748–761.
  • Uhlmann B, Goyette S, Beniston M. 2009. Sensitivity analysis of snow patterns in Swiss ski resorts to shifts in temperature, precipitation and humidity under conditions of climate change. Int J Climatol. 29(8):1048–1055.
  • Viste E, Sorteberg A. 2015. Snowfall in the Himalayas: an uncertain future from a little-known past. Cryosphere. 9(3):1147–1167.
  • Wang W, Huang X, Deng J, Xie H, Liang T. 2014. Spatio-temporal change of snow cover and its response to climate over the Tibetan Plateau based on an improved daily cloud-free snow cover product. Remote Sens. 7(1):169–194.
  • Winstral A, Marks D, Gurney R. 2013. Simulating wind-affected snow accumulations at catchment to basin scales. Adv Water Resour. 55:64–79.
  • Yin D, Cao X, Chen X, Shao Y, Chen J. 2013. Comparison of automatic thresholding methods for snow-cover mapping using Landsat TM imagery. Int J Remote Sens. 34(19):6529–6538.
  • Zhang H, Zhang F, Zhang G, Che T, Yan W, Ye M, Ma N. 2019. Ground-based evaluation of MODIS snow cover product V6 across China: implications for the selection of NDSI threshold. Sci Total Environ. 651:2712–2726.
  • Zhou X, Xie H, Hendrickx JM. 2005. Statistical evaluation of remotely sensed snow-cover products with constraints from streamflow and SNOTEL measurements. Remote Sens Environ. 94(2):214–231.

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