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01-12-2016 | Original Article

Investigating changes in Himalayan glacier in warming environment: a case study of Kolahoi glacier

Authors: Mohammd Rafiq, Anoop Mishra

Published in: Environmental Earth Sciences | Issue 23/2016

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Abstract

There are strong evidences of melting in Himalayan glaciers at unprecedented rate in the past few decades. In the present study, the changes in Kolahoi glaciers in Himalaya are evaluated. Possible reasons behind these changes are also investigated. For this purpose, the changes in black carbon concentration, precipitation temperature and snow depth are investigated. A case study was carried out for the Kolahoi glacier situated at an altitude of 5245 m above sea level. The glacier area and snout change from 1857 to 2015 are investigated. It is reported in this study that the glacier has shrunk from 35 to 09.88 Sq Km. The rate of recession measured from 1922 to 2015 is reported to be 73.26 m per year. Furthermore, the rate of recession of snout is found to be 16.41 m per year from 1857 to 2015. The shirking of glacier area is linked to reduction in snow depth which in turn is affected by the increase in black carbon concentration, temperature and reduction in precipitation. Reanalysis data show that there is decrease of about 1.08 ± 0.65 cm per decade in snow depth over Kolahoi glacier during 1979 to 2013. There are decadal increasing trends of about 76 nanogram/m² (statistically significant) and 0.39 °C (insignificant) in black carbon concentration and temperature, respectively, over Kolahoi. A decreasing trend of about 2.9 mm/month per decade in precipitation over the study area is also reported. Impact of increase in regional temperature on changes in snow depth is also quantified using inter-annual difference technique. It is reported that there is decrease of about 71 ± 24% in snow depth for each degree increase in temperature over Kolahoi. Reduction in snow depth as a result of increase in black carbon concentration, temperature and reduction in precipitation might have resulted in the shrinking of the Kolahoi glacier.

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Arendt AA, Echelmeyer KA, Harrison WD, Lingle CS, Valentine VB (2002) Rapid wastage of Alaska glaciers and their contribution to rising sea level. Science 297(5580):382–386CrossRef

Bhambri R, Bolch T, Chaujar RK (2012) Frontal recession of Gangotri Glacier, Garhwal Himalayas, from 1965 to 2006, measured through highresolution remote sensing data. Curr Sci 102(3):489–494

Bolch T (2007) Climate change and glacier retreat in northern Tien Shan (Kazakhstan/Kyrgyzstan) using remote sensing data. Global Planet Change 56(1–2):1–12CrossRef

Bond TC, Doherty SJ, Fahey DW, Forster PM, Berntsen T, DeAngelo BJ, Flanner MG, Ghan S, Kärcher B, Koch D, Kinne S (2013) Bounding the role of black carbon in the climate system: a scientific assessment. J Geophys Res Atmos 118(11):5380–5552CrossRef

Granshaw FD, Fountain AG (2006) Glacier change (1958–1998) in the north Cascades national park complex, Washington, USA. J Glaciol 52(177):251–256CrossRef

Haeberli W, Frauenfelder R, Hoelzle M, Maisch M (1999) On rates and acceleration trends of global glacier mass changes. Geografiska Annaler: Ser A Phys Geogr 81(4):585–591CrossRef

Hall DK, Bayr KJ, Schöner W, Bindschadler RA, Chien JY (2003) Consideration of the errors inherent in mapping historical glacier positions in Austria from the ground and space (1893–2001). Remote Sens Environ 86(4):566–577CrossRef

Intergovernmental Panel on Climate Change (2001) IPCC third assessment report- climate change 2001. Working Group I: Technical Summary. Geneva, WMO and UNEP

Intergovernmental Panel on Climate Change (2007) Summary for policymakers. In: Solomon S et al (eds) Climate change 2007: the physical science basis, in contribution of working group 1 to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, pp 1–18CrossRef

Jacobi HW, Lim S, Ménégoz M, Ginot P, Laj P, Bonasoni P, Stocchi P, Marinoni A, Arnaud Y (2015) Black carbon in snow in the upper Himalayan Khumbu Valley, Nepal: observations and modeling of the impact on snow albedo, melting, and radiative forcing. Cryosphere Discuss 9:1685–1699CrossRef

Jianping Y, Yongjian D, Rensheng C, Shiyin L, Anxin L (2004) Causes of glacier change in the source regions of the Yangtze and Yellow rivers on the Tibetan Plateau. J Glaciol 49(167):539–546CrossRef

Kääb A (2002) Monitoring high-mountain terrain deformation from repeated air- and spaceborne optical data: examples using digital aerial imagery and ASTER data. ISPRS J Photogr Remote Sens 57(1–2):39–52CrossRef

Kanth TA, Shah AA, ul Hassan Z (2011) Geomorphologic character & receding trend of Kolahoi Glacier in Kashmir Himalaya. Recent Res Sci Technol 3(9):68–73

Kaul MN (1990) Glacial and fluvial geomorphology of Western Himalaya: Liddar Valley. South Asia Books, Columbia

Khromova TE, Dyurgerov MB, Barry RG (2003) Late-twentieth century changes in glacier extent in the Ak-shirak Range, Central Asia, determined from historical data and ASTER imagery. Geophys Res Lett 30(16):1863

Kuhn M (1993) Possible future contribution to sea level change from small glaciers. In: Warric RA et al (eds) Climate and Sea level change: observations, projections and implications. Cambridge University Press, Cambridge, pp 134–143

Kundzewicz ZW, Mata LJ, Arnell NW, Döll P, Jimenez B, Miller K, Oki T, Şen Z, Shiklomanov I (2008) The implications of projected climate change for freshwater resources and their management. Hydrol Sci J Des Sci Hydrol 53(1):3–10CrossRef

Leick A, Rapoport L, Tatarnikov D (2015) GPS satellite surveying. Wiley, New YorkCrossRef

Maskey S, Uhlenbrook S, Ojha S (2011) An analysis of snow cover changes in the Himalayan region using MODIS snow products and in situ temperature data. Clim Change 108:391. doi:10.1007/s10584-011-0181-y CrossRef

Mishra A (2012) Estimation of rainfall from Satellite Infrared and Microwave measurements over Indian tropics. Gujarat University

Mishra A, Liu SC (2014) Changes in precipitation pattern and risk of drought over India in the context of global warming. J Geophys Res 119:7833–7841

Mishra A, Srinivasan J (2013) Did a cloud burst occur in Kedarnath during 16 and 17 June 2013? Curr Sci 105(10):1351–1352

Neve EF (1910) Mt. Kolahoi and its northern glacier. Alp J 25:39–42

Odell NE (1963) The Kolahoi northern glacier, Kashmir. J Glaciol 4(35):633–635CrossRef

Oerlemans J (1994) Quantifying global warming from the retreat of glaciers. Science 264:243–245CrossRef

Paul F, Kääb A, Maisch M, Kellenberger T, Haeberli W (2002) The new remote-sensing-derived Swiss glacier inventory: I. Methods. Ann Glaciol 34(1):355–361CrossRef

Paul F, Kääb A, Haeberli W (2007) Recent glacier changes in the Alps observed by satellite: consequences for future monitoring strategies. Global Planet Change 56(1):111–122CrossRef

Rafiq M, Rashid I, Romshoo SA (2016) Estimating land surface temperature and its lapse rate over Kashmir Valley Using MODIS Data. In: Geostatistical and geospatial approaches for the characterization of natural resources in the environment. Springer International Publishing, New York, pp 723–728

Ramirez E, Francou B, Ribstein P, Descloitres M, Guérin R, Mendoza J, Gallaire R, Pouyaud B, Jordan E (2001) Small glaciers disappearing in the tropical Andes: a case-study in Bolivia: Glacier Chacaltaya (16° S). J Glaciol 47 (157):187–194 (Abstract)

Rignot E, Bamber JL, Van Den Broeke MR, Davis C, Li Y, Van De Berg WJ, Van Meijgaard E (2008) Recent Antarctic ice mass loss from radar interferometry and regional climate modelling. Nat Geosci 1(2):106–110CrossRef

Romshoo SA, Dar RA, Rashid I, Marazi A, Ali N, Zaz SN (2015) Implications of shrinking cryosphere under changing climate on the streamflows in the Lidder catchment in the Upper Indus Basin, India. Arct Antarct Alp Res 47(4):627–644CrossRef

Sharma E, Bhuchar S, Xing MA, Kothyari BP (2007) Land use change and its impact on hydro-ecological linkages in Himalayan watersheds. Trop Ecol 48(2):151–161

Singh P, Bengtsson L (2004) Hydrological sensitivity of a large Himalayan basin to climate change. Hydrol Process 18(13):2363–2385CrossRef

Srinivasan J (2013) Predicting and managing extreme rainfall. Curr Sci 105(1):7–8

Sunehra D (2013) Estimation of prominent global positioning system measurement errors for Gagan applications. Eur Sci J 9(15):66–79

University of Texas Libraries (2016) http://www.lib.utexas.edu/maps/topo/india_253k/. Accessed 25 Feb 2016

Viste E, Sorteberg A (2015) Snowfall in the Himalayas: an uncertain future from a little-known past. The Cryosphere 9:1147–1167CrossRef

Ye Q, Kang S, Chen F, Wang J (2006) Monitoring glacier variations on Geladandong mountain, central Tibetan Plateau, from 1969 to 2002 using remote-sensing and GIS technologies. J Glaciol 52(179):537–545CrossRef

Title: Investigating changes in Himalayan glacier in warming environment: a case study of Kolahoi glacier
Authors: Mohammd Rafiq
Anoop Mishra
Publication date: 01-12-2016
Publisher: Springer Berlin Heidelberg
Published in: Environmental Earth Sciences / Issue 23/2016
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-016-6282-1

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