Water quality assessment and monitoring of Kashmir Himalayan freshwater springs-A case study

Authors

  • Sami Ullah Bhat Department of Environmental Science, School of Earth and Environmental Sciences, University of Kashmir Srinagar-190006
  • Ashok K. Pandit Centre of Research for Development, School of Biological Sciences, University of Kashmir Srinagar-190006

Keywords:

hydrochemical facies, water resource, climate change

Abstract

The present study envisages the importance of monitoring and management of freshwater springs of Kashmir Himalaya due to role they play in meeting ever-increasing drinking water demands and maintaining various ecosystem services. Therefore, some of the most pressing issues fundamental to the existence of springs is their monitoring and management because of their geological, ecological, scientific, cultural, religious and societal importance. Despite the key role that they play, springs are today continuously facing various types of threats. Springs have attained recently an extraordinary importance as they play role in providing drinking water, irrigation, sustaining habitats for fisheries, aquatic biodiversity, endemism, spiritual enrichment, recreation, aesthetics etc. especially in scenario of climate change threat predicted for Himalayas. In this backdrop a study directed to assess water quality status and potential of springs to offer the solution to ever-increasing water shortages was carried out. Identification of main threats to spring ecosystems and their subsequent monitoring and management in Kashmir Himalaya has been pleaded in this article. Major research highlights of the work revealed very well to excellent water quality class and Piper trilinear diagram of spring water depicted Ca–Mg–HCO3 water type. ANOVA (Analysis of Variance) revealed significant variations whilst Principal Component Analysis (PCA) generated four principal components (PC1, PC2, PC3 and PC4) with higher Eigen values of 1.0 or more (1.4-9.5) accounting for 34.34, 30.03, 18.50 and 12.4% of the total variance respectively. Consequently, majority of the physico-chemical parameters (95.28%) loaded under PC1 and PC2 were having strong positive loading (>0.60) and are mainly responsible for regulating the hydrochemistry of spring waters. Cluster analysis revealed that springs like Kokernag, Achabal, Sherebagh, and Cheshmashahi and Dobinag fall in same cluster having 47-78% similarity while Verinag, Indraznag and Dobinag fall almost in same cluster showing similarity range of 61-80%.

References

APHA., 2005. Standard Methods for Examination of Water and Waste Water. Washington DC, USA, American Public Health Association: 1220.

Back, W., Hanshaw, B.B., 1965. Advances in hydroscience. In: chemical Geohydrology, Academic Press, New York, 11, 1–49.

Barquín, J., Scarsbrook, M., 2008. Management and conservation strategies for cold water springs. Aquatic Conserv: Mar. Freshw. Ecosyst. 18: 580–591. doi:10.1002/aqc.884

Bhat, F.A., Yousuf, A.R., 2002. Ecology of periphytic community of seven springs of Kashmir. Journal of Research and Development 2, 47–59.

Bhat, S.U., and Pandit, A.K., 2018. Hydrochemical Characteristics of Some Typical Freshwater Springs - A Case Study of Kashmir Valley Springs Intl. J. Water Resources & Arid Environ., 7(1), 90–100.

Cantonati, M., Cox, E.J., Jutner, I., 2011. Springs: neglected key habitats for biodiversity conservation Introduction to the Special Issue, Journal of Limnology 1–3. doi:10.4081/jlimnol.2011.s1.1

Cantonati, M., Füreder,L., Gerecke, R., Jüttner, I., Cox, E.J., 2012. Crenic habitats, hotpots for freshwater biodiversity conservation: toward an understanding of their ecology. Freshwater Science 31, 463–480. doi:10.1899/11-111.1

Cole, G.A., 1983.

Text Book of Limnology 3rd

Ed. St. Louis, C.V. Mosby.

Coward, J.M.H., Waltham, A.C., Bowser, R.J., 1972. Karst springs in the Vale of Kashmir. Journal of Hydrology 16, 213–223. doi:10.1016/0022-1694(72)90053-4

Cuthbert, M.O., Ashley, G.M., 2014. A spring forward for hominin evolution in East Africa. PLoS ONE 9:e107358. doi:10.1371/journal.pone.0107358

Digest of Statistics 2011-12. Directorate of Economics and Statistics, Planning and Development Department, Govt. of Jammu and Kashmir, India.

Dikeogu, T.C., Okeke, O.C., Ogbekhiulu, L.O., Ogbenna, P.C., 2018. Major ion chemistry and hydrochemical processes of Ngeneagu spring water at Akpugoeze, Oji river, Enugu, southeastern Nigeria International Journal of Advanced Academic Research | Sciences, Technology & Engineering. 4(2), 41–53.

Elhatip, H., 1997. The influence of karst features on environmental studies in Turkey. Environmental Geology 31, 27–33. doi:10.1007/s002540050160

Ettazarini, S., 2005. Processes of water-rock intereaction in the Turonian aquifer of Oum Er-Rabia Basin, Morocco. Environmental Geology 49(2), 293–299. doi:10.1007/s00254-005-0088-x

Fatchen, T.J., 2000. Mound springs management planning: management issues, strategies, and prescriptions for mound springs in far north South Australia. South Australian Department for Environment and Heritage, Adelaide.

Ford, D., Williams, P., 2007.

Karst Hydrogeology and Geomorphology

. John Wiley & Son Ltd, England.

Fortner, S.K., Lyons, W.B., Carey, A.E., Shipitalo, M.J., Welch, S.A., Welch, K.A., 2012. Silicate weathering and CO2 consumption within agricultural landscapes, the Ohio-Tennessee River Basin, USA. Biogeosciences, 9, 941–955. doi:10.5194/bg-9-941-2012

Giedraitiene, J., Satkunas, J., Graniczny, M., Dokto,r S., 2002. The chemistry of groundwater: A geoindicator of environmental change across the Polish-Lithuanian border. Environmental Geology 42, 743–749. doi:10.1007/s00254-002-0555-6

Gupta, A., Kulkarni, H., 2017. Inventory and revival of springs in Himalayas for Water Security.-Sustainable Development of Mountains of Indian Himalayan Region.

Hartnett, F.M., 2000. Florida’s springs: strategies for protection and restoration. Florida Department of Environmental Protection, Tallahassee, FL.

Haynes, C.V. Jr., 2008. Quaternary caldron springs as paleoecological archives. Pp. 76–97 In: L.E. Stevens, L.E. and V.J. Meretsky, (Eds.), Aridland Springs of North America: Ecology and Conservation. University of Arizona Press, Tucson

Hoffsten, P.O., Malmqvist, B., 2000. The macroinvertebrate fauna and hydrogeology of springs in central Sweden. Hydrobiology 436, 91–104.

Horton, R.R., 1965. An index number system for rating water quality. J. Wat. Pollut. Control. Fed 37, 300–306.

Hynes, H.B.N., 1970.

The Ecology of Running Waters

. University of Toronto Press.

Imbach, T., 1993. Environmental hydrogeology of a karst system with thermal and normal ground waters: examples from the Bursa region (Turkey). Proc. Hydrogeological Processes in Karst Tarranes, IAHS. 207, 7–13.

Jeelani, G., 2004. Effect of subsurface lithology on hydrochemistry of springs of a part of a Kashmir Himalaya. Himalayan Geology 25(2), 145–151.

Kadiri, M.O., 2000. Limnological studies of two contrasting but closely linked springs in Nigeria, West Africa. Plant Biosystems 134(2), 123–131. doi:10.1080/11263500012331358394

Katz, B.G., 2004. Nitrate contamination in karst ground water. In: D. Culver, W. White (Eds.),

Encyclopedia of Caves

. Elsevier Science, Amsterdam, Netherlands.

Katz, B.G., Böhlke, J.K., Hornsby, H.D., 2001. Timescales for nitrate contamination of spring waters, northern Florida. Chemical Geology, 179, 167–186. doi:10.1016/S0009-2541(01)00321-7

Katz, B.G., Griffin, D.W., Davis, J.H., 2009. Groundwater quality impacts from the land application of treated municipal wastewater in a large karstic spring basin: Chemical and microbiological indicators. Science of the Total Environment. 407, 2872–2886. doi:10.1016/j.scitotenv.2009.01.022

Kilroy, G., Coxon, C., 2005. Temporal variability of phosphorus fractions in Irish Karst springs. Environmental Geology 47, 421–430. doi:10.1007/s00254-004-1171-4

Kurian, M., 2017. The water-energy-food nexus Trade-offs, thresholds and transdisciplinary approaches to sustainable development. Env. Sci. Policy. 68, (2017):97–106. doi:10.1016/j.envsci.2016.11.006

Liu, Z.Q., Li, H.S., Wang, J., 2007. Seasonal, diurnal and storm-scale hydrochemical variations of typical epikarst springs in subtropical karst areas of SW China: Soil CO2 and dilution effects. Journal of Hydrology 337, 207–223. doi:10.1016/j.jhydrol.2007.01.034

McGowan, W., 2000. Water processing: residential, commercial, light-industrial, 3rd Ed. Lisle, IL, Water Quality Association.

Meinzer, R.O.E., 1923. Outline of ground-water hydrology, with definitions. U.S.Geol. Surv. Water- Supply. 494, 1–69.

Mohan, R., Singh, A.K., Tripathi, J.K., Chowdhary, G.C., 2000. Hydrochemistry and quality assessment of groundwater in Naini industrial area, Allahabad district, U.P. Journal of Geological Society of India. 55, 77–89.

Nathenson, M., Thompson, J.M., White, L.D., 2003. Slightly thermal springs and non-thermal springs at Mount Shasta, California: Chemistry and recharge elevations. Journal of Volcanology and Geothermal Research. 121, 137–153. doi:10.1016/S0377-0273(02)00426-2

Pandit, A.K., Rather, G.R., Rashid, H.U., 2005. Comparative limnology of two religiously important springs of Kashmir. Journal of Research and Development 5, 57–62.

Panno, S.V., Kelly, W.R., 2004. Nitrate and herbicide loading in two groundwater basins of Illinois sinkhole plain. Journal of Hydrology 290, 229–242. doi:10.1016/j.jhydrol.2003.12.017

Panno, S.V., Hacjley, K.C., Hwang, H., Kelly, W.R., 2001. Determination of the sources of nitrate contamination in karst springs using isotopic and chemical indicators. Chemical Geology. 179, 113–28. doi:10.1016/S0009-2541(01)00318-7

Panno, S.V., Hacjley, K.C., Hwang, H., Greenberg, S.E., Krapac, I.G., Landsberger, S.O., Kelly, D.J., 2006. Characterization and identification of Na-Cl sources in ground water. Ground Water 44, 176–187. doi:10.1111/j.1745-6584.2005.00127.x

Pedersen, O., Colmer, T.D. Sand-Jensen, K., 2013. Underwater photosynthesis of submerged plants - recent advances and methods. Frontiers in plant science, doi:10.3389/fpls.2013.00140

Rosenau, J.C., Faulkner, G.L., Hendry, C.W., Hull, R.W., 1977. Springs of Florida: Florida Geological Survey Bulletin 31 (Revised).

Sada, D.W., Sharpe, S.E., 2004. Conference Proceedings, Spring-fed Wetlands: Important Scientific and Cultural Resources of the Intermountain Region, 7–9 May 2002, Las Vegas, NV, DHS publication No. 41210.

Sada, D.W., Williams, J.E.; Silvey, J.C., Halford, A., Ramakka, J., Summers, P., Lewis, L., 2001: A guide to managing, restoring, and conserving springs in the Western United States. Desert Research Institute, Reno, Nevada. 70.

Shrestha, R.B., Jayesh, D., Mukherji, A., Madhav, D., Kulkarni, H., Mahamuni, K., Bhuchar. S., Bajrachary, S., 2018. ICIMOD Manual. Protocol for Reviving Springs in the Hindu Kush Himalaya: A Practitioner’s Manual. 74.

Shuster, E.T., White, W.B., 1971. Seasonal fluctuations in the chemistry of limestone spring. A possible means for characterizing carbonate aquifers Journal of Hydrology 14, 93–128. doi:10.1016/0022-1694(71)90001-1

Smith, H., Wood, P.J., 2002. Flow permanence and macroinvertebrate community variability in lime stone spring systems. Hydrobiology 487, 45–58.

Srinivasan, V., Konar, M., Sivapalan, M., 2017. A Dynamic framework for Water Security. Water Security 1, 12–20. doi:10.1016/j.wasec.2017.03.001

Steidtmann, E., 1911. The Evolution of Limestone and Dolomite. I The Journal of Geology, 19 (4), 323–345. doi:10.1086/621853

Symonds, R.B., Gerlach, T.M., Reed, M.H., 2001. Magmatic gas scrubbing: implications for volcano monitoring. Journal of Volcanology and Geothermal Research. 108, 303–341. doi:10.1016/S0377-0273(00)00292-4

Ternan, J.L., 1972. Comments on the use of a calcium hardness variability index in the study of carbonate aquifers: with reference to the central Pennines, England. Journal of Hydrology 16, 317- 321. doi:10.1016/0022-1694(72)90136-9

Theineman, A., 1922. Hydrobiologissch Untersuchungen an Quellen. Archiv. Für. Hydrobiologie 14, 151–190.

Tiwari, P.C., 2000. Land-use changes in Himalaya and their impact on the plains ecosystem: Need for sustainable land use. Land Use Policy, 17(2), 101–111. doi:10.1016/S0264-8377(00)00002-8

Tiwari, T.N., Mishra, M., 1985. A preliminary assignment of water quality index to major Indian rivers. IJEP. 5 (4), 276–279.

Wagener, T., Sivapalan, M., Troch, P.A., McGlynn, B.L., Harman, C.J., Gupta, H.V., Kumar, P., Rao, P.S.C., Basu, N.B., Wilson, J.S., 2010. The future of hydrology: an evolving science for a changing world, Water Resour. Res. 46, W05301 doi:10.1029/2009WR008906

Wetzel, R.G., Likens, G.E., 2000. Limnological Analysis, 3rd edition. Springer Verlag New York Publications.

Williams, P.W., 1993. Karst Terrains; Environmental Changes and Human Impacts, Catena Supplement. 25, 268.

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Published

2020-07-02

Issue

Vol. 23 No. 3 (2020): Aquatic Ecosystem Health & Management

Section

Research article

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