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Hydro-geochemical analysis of meltwater draining from Bilare Banga glacier, Western Himalaya

  • Ramesh Kumar
  • Rajesh KumarEmail author
  • Atar Singh
  • Shaktiman Singh
  • Anshuman Bhardwaj
  • Anupma Kumari
  • Ravindra Kumar Sinha
  • Akhilesh Gupta
Research Article - Hydrology

Abstract

The changing climate is affecting the melting process of glacier ice and snow in Himalaya and may influence the hydro-geochemistry of the glacial meltwater. This paper represents the ionic composition of discharge from Bilare Banga glacier by carrying out hydro-geochemical analysis of water samples of melting season of 2017. The pH and EC were measured on-site in field, and others parameters were examined in the laboratory. The abundance of the ions observed in meltwater has been arranged in decreasing order for cations as Ca2+ > Mg2+ > Na+ > K+ and for anions as HCO3 > SO42− > Cl > NO3, respectively. Analysis suggests that the meltwater is mostly dominated by Ca2+ and HCO3. It has been observed that the ionic concentration HCO3 is dominant and Cl is the least in the catchment. Piper plot analysis suggests that the chemical composition of the glacier discharge not only has natural origin but also has some anthropogenic input. Hydro-geochemical heterogeneity reflected the carbonate-dominated features (Ca2+–HCO3) in the catchment. The carbonate weathering was found as the regulatory factor to control the chemistry of the glacial meltwater due to the high enrichment ratio of (Ca2+ + Mg2+) against TZ+ and (Na+ + K+). In statistical approach, PCA analysis suggests that geogenic weathering dynamics in the catchment is associated with carbonate-dominant lithology.

Keywords

Bilare Banga glacier Hydro-geochemistry Cations Anions Carbonate weathering 

Notes

Acknowledgement

The support of the Ministry of Earth Sciences (MoES/PAMC/H&C/61/2015-PCII, dated March 03, 2016) through the project on Shaune Garang glacier sanctioned to Dr. Rajesh Kumar (the PI of the project) is thankfully acknowledged which has been helpful in building the glaciological human resource whose support is vital in the sampling of the meltwater as well as in the analysis. The support of USAID through a project “Contribution to High Asia Runoff from Ice and Snow” (CHARIS) under the collaboration of University of Colorado, Boulder, USA, is also acknowledged. The USAID support through CHARIS project helped not only in the research work but also in producing three PhD theses of students working under me (Dr. Rajesh Kumar). The critical review of the paper and suggestions provided by the anonymous reviewers and editor has been vital in improving the quality of the paper, and authors are grateful for the suggestions.

References

  1. American Public Health Association (APHA) (1998) Standard methods for the examination of water and waste water, 20th edn. APHA, AWWA, WPCF, WashingtonGoogle Scholar
  2. Blum JD, Gazis CA, Jacobson AD, Chamberlain CP (1998) Carbonate versus silicate weathering in the Raikhot watershed within the High Himalayan Crystalline series. Geology 26(5):411–414CrossRefGoogle Scholar
  3. Chauhan DS, Hasnain SI (1993) Chemical characteristics, solute and suspended sediments load in meltwater draining Satopanth and Bhagirathi Kharak glaciers, Ganga basin, India. In: Young GJ (ed) Snow and glacier hydrology, vol 218. IAHS Press, Wallingford, pp 2–10Google Scholar
  4. Dutta S, Mujtaba SAI, Saini HS, Chunchekar R, Kumar P (2017) Geomorphic evolution of glacier-fed Baspa Valley, NW Himalaya: record of Late Quaternary climate change, monsoon dynamics and glacial fluctuations. In: Pant NC, Ravindra R, Srivastava D, Thompson LG (eds) The Himalayan Cryosphere: past and present, vol 462. Geological Society, London.  https://doi.org/10.1144/SP462.5 Google Scholar
  5. Haritashya UK, Kumar A, Singh P (2010) Particle size characteristics of suspended sediment transported in meltwater from the Gangotri Glacier, central Himalaya—an indicator of subglacial sediment evacuation. Geomorphology 122(1–2):140–152.  https://doi.org/10.1016/j.geomorph.2010.06.006 CrossRefGoogle Scholar
  6. Huang X, Sillanpää M, Duo B, Gjessing ET (2008) Water quality in the Tibetan Plateau: metal contents of four selected rivers. Environ Pollut 156(2):270–277CrossRefGoogle Scholar
  7. Iscen CF, Emiroglu O, Ilhan S, Arslan N, Yilmaz V, Ahiska S (2008) Application of multivariate statistical techniques in the assessment of surface water quality in Uluabat Lake, Turkey. Environ Monit Assess 144(1–3):269–276CrossRefGoogle Scholar
  8. Kanakiya RS, Singh SK, Sharma JN (2014) Determining the water quality index of an urban water body Dal Lake, Kashmir, India. IOSR J Environ Sci Toxicol Food Technol 08(12):64–71.  https://doi.org/10.9790/2402-081236471 CrossRefGoogle Scholar
  9. Karim A, Veizer J (2000) Weathering processes in the Indus River basin: implications from riverine carbon, sulfur, oxygen, and strontium isotopes. Chem Geol 170:153–177CrossRefGoogle Scholar
  10. Kotadiya NG, Acharya CA (2014) An assessment of lake water quality index of Manipu Lake of district Ahmedabad, Gujarat. Int J Sci Res 03(4):448–450Google Scholar
  11. Kumar K, Miral MS, Joshi S, Pant N, Joshi V, Joshi LM (2009) Solute dynamics of melt water of Gangotri glacier, Garhwal Himalaya, India. Environ Geol 58:1151–1159.  https://doi.org/10.1007/s00254-008-1592-6 CrossRefGoogle Scholar
  12. Kumar A, Verma A, Dobhal DP, Mehta M, Kesarwani K (2014) Climatic control on extreme sediment transfer from Dokriani Glacier during monsoon, Garhwal Himalaya (India). J Earth Syst Sci 123:109–120CrossRefGoogle Scholar
  13. Kumar R, Singh S, Kumar R, Singh A, Bhardwaj A, Sam L, Randhawa SS, Gupta A (2016) Development of a glaciohydrological model for discharge and mass balance reconstruction. J Water Resour Manag.  https://doi.org/10.1007/s11269-016-1364-0 Google Scholar
  14. Kumar R, Kumar R, Singh A, Sinha RK, Kumari A (2018a) Nanoparticles in glacial melt water. Mater Today Proc 5(3P1):9161–9166.  https://doi.org/10.1016/j.matpr.2017.10.037 CrossRefGoogle Scholar
  15. Kumar R, Kumar R, Singh S, Singh A, Bhardwaj A, Kumari A, Randhawa SS, Saha A (2018b) Dynamics of suspended sediment load with respect to summer discharge and temperatures in Shaune Garang glacierized catchment. Acta Geophys, Western Himalaya.  https://doi.org/10.1007/s11600-018-0184-4 CrossRefGoogle Scholar
  16. Lutz AF, Immerzeel WW, Shrestha AB, Bierkens MFP (2014) Consistent increase in High Asia’s runoff due to increasing glacier melt and precipitation. Nat Clim Change 4:587–592.  https://doi.org/10.1038/nclimate2237 CrossRefGoogle Scholar
  17. Maurer JM, Rupper SB, Schaefer JM (2016) Quantifying ice loss in the eastern Himalayas since 1974 using declassified spy satellite imagery. Cryosphere 10:2203–2215.  https://doi.org/10.5194/tc-10-2203-2016 CrossRefGoogle Scholar
  18. Meybeck M (1987) Global chemical weathering of surficial rocks estimated from river dissolved loads. Am J Sci 287:401–428CrossRefGoogle Scholar
  19. Mortatti J, Probst JL (2003) Silicate rock weathering and atmospheric/soil CO2 uptake in the Amazon basin estimated from river water geochemistry: seasonal and spatial variations. Chem Geol 197:177–196CrossRefGoogle Scholar
  20. Pant RR, Zhang F, Rehman FU, Wang G, Ming Y, Zeng C, Tang H (2018) Spatiotemporal variations of hydro-geochemistry and its controlling factors in the Gandaki River Basin, Central Himalaya Nepal. Sci Total Environ 622–623(2018):770–782.  https://doi.org/10.1016/j.scitotenv.2017.12.063 CrossRefGoogle Scholar
  21. Philip G, Sah MP (2004) Mapping repeated surges and retread of glaciers using IRS-1C/1D data: a case study of Shaune Garang glacier, northwestern Himalaya. Int J Appl Earth Obs Geoinf 6(2):127–141.  https://doi.org/10.1016/j.jag.2004.09.002 CrossRefGoogle Scholar
  22. Piper AM (1944) A graphic procedure in the geochemical interpretation of water analyses. Trans Am Geophy Union 25:914–928.  https://doi.org/10.1029/TR025i006p00914 CrossRefGoogle Scholar
  23. Piper AM (1953) A graphic procedure in the geochemical interpretation of water analysis. Ground water note 12. U.S. Dept. of the Interior, Geological Survey, Water Resources Division, Ground Water Branch, Washington, p 63Google Scholar
  24. Ramanathan AL (2007) Seasonal variation in the major ion chemistry of Pandoh Lake, Mandi district, Himachal Pradesh, India. Appl Geochem 22:1736–1747CrossRefGoogle Scholar
  25. Ravikumar P, Somashekar RK, Mehmood MA (2013) Water quality index to determine the surface water quality of Sankey tank and Mallathahalli Lake, Bangalore urban district, Karnataka, India. Appl Water Sci 3:247–261CrossRefGoogle Scholar
  26. Raymahasay BC (1986) Geochemistry of bicarbonate in the river water. J Geol Soc India 27:114–118Google Scholar
  27. Saleem M, Jeelani G, Shah RF (2015) Hydro geochemistry of Dal Lake and the potential for present, future management by using facies, ionic ratios, and statistical analysis. Environ Earth Sci 74(4):3301–3313.  https://doi.org/10.1007/s12665-015-4361-3 CrossRefGoogle Scholar
  28. Sam L, Bhardwaj A, Singh S, Kumar R (2015) Remote sensing in glacier velocity estimation and a novel approach for debris covered glaciers. Prog Phys Geogr.  https://doi.org/10.1177/0309133315593894 Google Scholar
  29. Schild A (2008) The case of the Hindu Kush–Himalayas: ICIMOD’s position on climate change and mountain systems. Mt Res Dev.  https://doi.org/10.1659/mrd.mp009 Google Scholar
  30. Sharma P, Ramanathan AL, Pottakkal JG (2013) Study of solute sources and evolution of hydro-geochemical processes of the Chhota Shigri Glacier meltwaters, Himachal Himalaya, India. Hydrol Sci J 58(5):1128–1143.  https://doi.org/10.1080/02626667.2013.802092 CrossRefGoogle Scholar
  31. Shekhar M, Bhardwaj A, Singh S, Ranhotra PS, Bhattacharyya A, Pal AK, Roy I, Torres JM, Zorzano MP (2017) Himalayan glaciers experienced significant mass loss during later phases of little ice age. Sci Rep 7:10305.  https://doi.org/10.1038/s41598-017-09212-2 CrossRefGoogle Scholar
  32. Shichang K, Dahe Q, Tandong Y (2000) A study on precipitation chemistry in the late summer in the northern slope of Mt. Xiaxabangma. Acta Sci Circumst 20(5):574–578Google Scholar
  33. Singh AK, Hasnain SI (1998a) Major ion chemistry and weathering control in a high altitude basin: Alaknanda River, Garhwal Himalaya, India. Hydrol Sci 43(6):825–843CrossRefGoogle Scholar
  34. Singh AK, Hasnain SI (1998b) Major ion chemistry and weathering control in a high altitude basin: Alaknanda River, Garhwal Himalaya, India. Hydrol Sci J 43(6):825–843.  https://doi.org/10.1080/02626669809492181 CrossRefGoogle Scholar
  35. Singh VB, Ramanathan AL (2015) Assessment of solute and suspended sediment acquisition processes in the Bara Shigri glacier meltwater (Western Himalaya, India). Environ Earth Sci 74:2009–2018CrossRefGoogle Scholar
  36. Singh AK, Mondal GC, Kumar S, Singh TB, Tewari BK, Sinha A (2008) Major ion chemistry, weathering processes and water quality assessment in upper catchment of Damodar River basin, India. Environ Geol 54(4):745–758.  https://doi.org/10.1007/s00254-007-0860-1 CrossRefGoogle Scholar
  37. Singh CK, Shashtri S, Mukherjee S (2011) Integrating multivariate statistical analysis with GIS for geochemical assessment of groundwater quality in Shiwaliks of Punjab, India. Environ Earth Sci 62:1387–1405CrossRefGoogle Scholar
  38. Singh VB, Ramanathan AL, Jose PG, Sharma P, Linda A, Azam MF, Chatterjee C (2012) Chemical characterisation of meltwater draining from Gangotri Glacier, Garhwal Himalaya, India. J Earth Syst Sci 121(3):625–636CrossRefGoogle Scholar
  39. Singh VB, Ramanathan AL, Jose PG, Kumar M (2014) Seasonal variation of the solute and suspended sediment load in Gangotri glacier meltwater, central Himalaya, India. J Asian Earth Sci 79:224–234CrossRefGoogle Scholar
  40. Singh VB, Ramanathan AL, Sharma P, Pottakkal JG (2015) Dissolved ion chemistry and suspended sediment characteristics of melt water draining from Chhota Shigri glacier, Western Himalaya, India. Arab J Geosci 8:281–293CrossRefGoogle Scholar
  41. Singh S, Kumar R, Bhardwaj A, Sam L, Shekhar M, Singh A, Kumar R, Gupta A (2016a) Changing climate and glacio-hydrology in Indian Himalayan Region: a review. Wiley Interdiscip Rev Clim Change 7(3):393–410.  https://doi.org/10.1002/wcc.39 CrossRefGoogle Scholar
  42. Singh VB, Ramanathan AL, Mandal A (2016b) Hydrogeochemistry of high-altitude lake: a case study of the Chandra Tal, Western Himalaya, India. Arab J Geosci 9(4):308.  https://doi.org/10.1007/s12517-016-2358-1 CrossRefGoogle Scholar
  43. Singh VB, Ramanathan AL (2017) Hydrogeochemistry of the Chhota Shigri glacier meltwater, Chandra basin, Himachal Pradesh, India: solute acquisition processes, dissolved load and chemical weathering rates. Environ Earth Sci 76(5):223CrossRefGoogle Scholar
  44. Singh S, Kumar R, Bhardwaj A, Kumar R, Singh A (2018) Changing climate and glacio-hydrology: a case study of Shaune Garang basin, Himachal Pradesh. Int J Hydrol Sci Technol.  https://doi.org/10.1504/IJHST.2018.10010353 Google Scholar
  45. Szopińska M, Szumińska D, Bialik RJ, Chmiel S, Plenzler J, Polkowska Z (2018) Impact of a newly-formed periglacial environment and other factors on fresh water chemistry at the western shore of Admiralty Bay in the summer of 2016 (King George Island, Maritime Antarctica). Sci Total Environ 613–614(2018):619–634.  https://doi.org/10.1016/j.scitotenv.2017.09.060 CrossRefGoogle Scholar
  46. Thomas J, Joseph S, Thrivikramji KP (2015) Hydro-chemical variations of a tropical mountain river system in a rain shadow region of the southern Western Ghats, Kerala, India. Appl Geochem 63:456–471CrossRefGoogle Scholar
  47. Tranter M, Brown GH, Raiswell R, Sharp MJ, Gurnell AM (1993) A conceptual model of solute acquisition by Alpine glacier meltwaters. J Glaciol 39(133):573–581CrossRefGoogle Scholar
  48. Vasanthavigar M, Srinivasamoorthy K, Prasanna MV (2013) Identification of groundwater contamination zones and its sources by using multivariate statistical approach in Thirumanimuthar sub basin, Tamil Nadu, India. Environ Earth Sci 68:1783–1795CrossRefGoogle Scholar
  49. Vetrimurugan E, Elango L, Rajmohan N (2013) Sources of contaminants and groundwater quality in the coastal part of a river delta. Int J Environ Sci Technol 10(3):473–486.  https://doi.org/10.1007/s13762-012-0138-3 CrossRefGoogle Scholar
  50. Wulf H, Bookhagen B, Scherler D (2010) Seasonal precipitation gradients and their impact on fluvial sediment flux in the Northwest Himalaya. Geomorphology 118:13–21CrossRefGoogle Scholar
  51. Xiao J, Jin ZD, Zhang F, Wang J (2012) Solute geochemistry and its sources of the ground waters in the Qinghai Lake catchment, NW China. J Asian Earth Sci 52:21–30.  https://doi.org/10.1016/j.jseaes.2012.02.006 CrossRefGoogle Scholar
  52. Zhu B, Yu J, Qin X, Rioual P, Jiang F, Liu Z, MuY LH, Ren X, Xiong H (2013) Identification of rock weathering and environmental control in arid catchments (northern Xinjiang) of Central Asia. J Asian Earth Sci 66:277–294.  https://doi.org/10.1016/j.jseaes.2013.02.005 CrossRefGoogle Scholar

Copyright information

© Institute of Geophysics, Polish Academy of Sciences & Polish Academy of Sciences 2019

Authors and Affiliations

  • Ramesh Kumar
    • 1
  • Rajesh Kumar
    • 1
    Email author
  • Atar Singh
    • 1
  • Shaktiman Singh
    • 1
    • 2
  • Anshuman Bhardwaj
    • 2
  • Anupma Kumari
    • 3
  • Ravindra Kumar Sinha
    • 3
    • 4
  • Akhilesh Gupta
    • 5
  1. 1.Department of Environmental Science, SBSRSharda UniversityGreater NoidaIndia
  2. 2.Department of Computer Science, Electrical and Space EngineeringLulea University of TechnologyLuleåSweden
  3. 3.Department of ZoologyPatna UniversityPatnaIndia
  4. 4.Nalanda Open UniversityPatnaIndia
  5. 5.DSTTechnology BhavanNew DelhiIndia

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