Assessment of water quality in disease burdened industrializing town of mid hills of North India
DOI:
https://doi.org/10.18203/2320-6012.ijrms20232780Keywords:
Assessment, Industrialization, Physico-chemical, Water pollution, Water quality index, Poor quality, MonsoonAbstract
Background: Anthropogenic activities associated with rapid urbanization and industrialization have deteriorated the water quality across the world. Rampant industrialization and poor water, sanitation and hygiene in an industrializing town of northern India necessitated the assessment of drinking water in the region.
Methods: The study of physico-chemical parameter of the water and water quality index of the most commonly used ten drinking water sources in 2017-2018 was undertaken. Grab water samples were collected during monsoon, the rainy season (June, July and August) and post monsoon (September, October and November) during the years 2017 and 2018 by following the standard procedures. Weighted arithmetic index method was used for the water quality index (WQI) analysis.
Results: Pooled analysis inferred water pH, temperature, total dissolved solids and carbonated oxygen demand to be within, whereas, electrical conductivity (91.00-431.50 µS/cm), turbidity (1.00-4.30 mg/l), dissolved oxygen (6.53-7.23 mg/l) and biological oxygen demand (6.12-7.62 mg/l), exceeding the Bureau of Indian standards permissible limits. Calcium, nitrate, chlorides and zinc were within limits, magnesium concentrations (9.16-29.35 mg/l) were below whereas lead (0.06-0.62 mg/l), chromium (0.01-0.12 mg/l), cadmium (0.00-0.25 mg/l) and mercury (0.00-0.08 mg/l) were above the standards. WQI was above 50 in all the drinking water sources.
Conclusions: Water was of poor quality and unsuitable for drinking purposes, indicating alarming water pollution. WQI of the various drinking water sources of the region deteriorated more in the monsoon season as compared to the post monsoon season.
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References
Deng A, Ye C, Liu W. Spatial and seasonal patterns of nutrients and heavy metals in twenty seven rivers draining into the South China Sea. Water. 2018;10:1-15.
Singh AK, Bhardwaj SK. Assessment of spatial and temporal variation of water quality in mid hills of North Western Himalayas- a water quality index approach. Current World Environ. 2019;14:37-48.
Singh A, Chawla S, Bharti. Role of Integrated Surveillance Programme in eliciting an E coli 0157: H7 gastroenteritis outbreak at tribal girls hostel, Solan, H.P. Schol J App Med Sci. 2017;5:717-22.
Singh AK, Bhardwaj RR, Bhaglani DK, Chawla S. Surveillance system eliciting an outbreak of gastroenteritis due to bacillus cereus associated with consumption of contaminated food. Int J Recent Sci Res. 2018;9:26594-7.
Brown RM, McClelland NI, Deininger RA, Tozer RG. A water quality index-Do we care? Water Sew Work. 1970:339-43.
Singh R, Sukhatme BV. Optimum Stratification. Ann Stat Math. 1969;21:515-28.
Tozer RG. Standard methods for the examination of water and waste water. 24th ed. Washington DC: 2017;1496.
Gomez KA, Gomez AA. Statistical procedures for agricultural research with emphasis on rice. New York: John Wiley and Sons; 1984:680.
Brown RM, McClelland NI, Deininger RA, Tozer RG. A water quality index- Do we care? Water and Sewage Works. Available at: http://scirp.org/reference/ referencespaper.aspx?referenceid=2177600. Accessed on 21 December 2022.
Rana A, Bhardwaj SK, Thakur M. Surface water quality and associated aquatic insect fauna under different land uses in Solan (district Solan), Himachal Pradesh. Indian J Ecol 2016;43(1):58-64.
Bouslah S, Djemili L, Houichi L. Water quality index assessment of Koudiat Medouar Reservoir, northeast Algeria using weighted arithmetic index method. J Water Land Develop. 2017;35:221-8.
Kumar RN, Solanki R, Kumar JIN. Seasonal variation in heavy metal concentration in water and sediments of river Sabarmati and Kharicut canal at Ahmedabad, Gujarat. Environ Monitor Assess. 2013;185:359-68.
Sangeeta P, Neha P. Monitoring of seasonal variation in physicochemical water parameters in Nalasopara region. J Ecosys Ecograph. 2015;5:156.
Liyanage CP, Yamada K. Impact of population growth on the water quality of natural water bodies. Sustainibility. 2017;9(8):1405.
Mahananda MR, Mohanty BP, Behera NR. Physico-chemical analysis of surface and ground water of Bargarh district, Orissa, India. Int J Recent Res App Sci. 2010;2(3):284-95.
Chang CL, Liao CS. Assessing the risk posed by high turbidity water to water supplies. Environ Monit Assess. 2012;184(5):3127-32.
Sengupta, P. Potential health impacts of hard water. Int J Prevent Med. 2013;4(8):866-75.
Mohamed HP, Zahir HA. Seasonal variations of ground water quality in and around Dindigul town, Tamil Nadu, India. Der Chemica Sinica. 2017;8(2): 235-41.
Kashyap R, Verma KS, Bhardwaj SK. Pollution potential assessment of Markanda river around Kala Amb industrial town of Himachal Pradesh India. Int J Sci Nature. 2015;6(4):606-12.
Mathuram T, Chandran M, Dinakaran K. Study on physicochemical parameters of surface water of Vaigai river near Madurai city, Tamil Nadu, India. Int J Creat Res Thoughts. 2017;5:2368-91.
Cobbina SJ, Duwiejuah AB, Quansah R, Obiri S, Bakobie N. Comparative assessment of heavy metals in drinking water sources in two small scale mining communities in Northern Ghana. Int J Environ Res Public Health. 2015;12:10620-34.
Annan ST, Sanful P, George LY, Yandam R. Spatial and temporal patterns of variation in environmental quality of water and sediments of streams in mined and unmined areas with emphasis on mercury (Hg) and arsenic (As). J Geosci Environ Protect. 2018;6:125-40.
Brief industrial profile of Solan district 2014-15, Micro, Small and Medium Enterprises Development Institute. Government of India. Available at: https://www.msmedhimachal.nic.in. Accessed on 10 March 2022.
Fick J, Soderstorm H, Lindberg RH, Phan C, Tysklind M, Larsson DGJ. Contamination of surface, ground and drinking water from pharmaceutical production. Environ Toxicol Chem. 2009;28(12):2522-7.
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