Abstract
The objective of this study is to estimate the aquifer vulnerability in the West Bokaro coalfield, Jharkhand, India, by using a geographic information system (GIS)-based DRASTIC model. The DRASTIC model incorporates seven hydrogeological data, i.e. depth of water table, net recharge, aquifer media, soil media, topography, impact of vadose zone and hydraulic conductivity. The model was validated by comparing the model output (vulnerability index map) with a statistical analysis and the actual SO4 2− and Fe concentrations in the groundwater of the study area. Thirty-three well samples were collected from the West Bokaro coalfield area. These were analyzed in the laboratory to measure the level of SO4 2− and Fe in the groundwater. The GIS-based DRASTIC result showed that 0.06 % of the area fell into the low-vulnerability zone and 10.8 % fell into the moderate vulnerability zone. About 87.7 % of the study area fell into the moderate to high-vulnerability zone, and 1.4 % of the study area was classified as the highly vulnerable zone. From the vulnerability map, it was observed that some of the western part and some of the middle part of the study area lay in the high-vulnerability zone, and therefore, they were more susceptible to aquifer pollution. The geogenic and anthropogenic activities are responsible for the high vulnerability in the study area. The shallow water level, topography, high net recharge and permeable vadose zone of the area served as the major influential parameters in mapping the vulnerability. The mining and related activities are also responsible for the high aquifer vulnerability of the area. The aquifer vulnerability maps generated in this study could also be used for the management of future water resources and environmental planning in all the mining regions.
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References
Al Zebet T (2002) Evaluation of aquifer vulnerability to contamination potential using the DRASTIC method. Environ Geol 43:203–208
Albinet M, Margat J (1970) Cartographie dela vulnerability pollution des nappes d’eau souterraine [Mapping of groundwater vulnerability to contamination]. Bull BRGM 2(4):13–22
Aller L, Bennet T, Leher JH, Petty RJ, Hackett G (1987) DRASTIC: a standardized system for evaluating ground water pollution potential using hydro-geological settings. EPA 600/2–87-035:622
Baalousha H (2006) Vulnerability assessment for the Gaza Strip, Palestine using DRASTIC. Environ Geol 50:405–414
Babiker IS, Mohamed MA, Hiyama T, Kato K (2005) A GIS-based DRASTIC model for assessing aquifer vulnerability in Kakamigahara Heights, Gifu Prefecture, central Japan. Sci Total Environ 345:127–140
Bhuiyan MA, Islam MA, Dampare SB, Parvez L, Suzuki S (2010) Evaluation of hazardous metal pollution in irrigation and drinking water systems in the vicinity of a coal mine area of northwestern Bangladesh. J Hazard Mater 179(1):1065–1077
Chitsazan M, Akhtari Y (2009) A GIS-based DRASTIC model for assessing aquifer vulnerability in Kherran Plain, Khuzestan, Iran. Water Resour Manage 23(6):1137–1155
Civita M, M De Maio (1997) SINTACS Un sistema parametrico per la valutazione e la cartografia della vulnerabilità degli acquiferi all’inquinamento. Metodologia e automazione. Pitagora Editrice, Bologna, 191
Ckakraborty S, Paul PK, Sikdar PK (2007) Assessing aquifer vulnerability to arsenic pollution using DRASTIC and GIS of north Bengal Plain: a case study of English Bazar Block, Malda District, west Bengal, India. J Spatial Hydro 7(1):101–121
COST 65 (1995) Hydrogeological aspects of groundwater protection in karstic areas, Final report (COST action 65). European Commission, Directorate-General XII Science, Research and Development, Report EUR 16547 EN, Brussels, p. 446
Doerfliger N, Zwahlen F (1998) Practical guide, groundwater vulnerability mapping in karstic regions (EPIK). Swiss Agency for the Environment, Forests and Landscape (SAEFL), Bern, 56 pp
Edet A (2014) An aquifer vulnerability assessment of the Benin Formation aquifer, Calabar, southeastern Nigeria, using DRASTIC and GIS approach. Environ Earth Sci 71(4):1747–1765
Farjad B, Mohd B, Shafri HZ, Mohamed TA, Pirasteh S, Wijesekara N (2012) Groundwater intrinsic vulnerability and risk mapping. Proc ICE-Water Manage 165(8):441–450
Foster SD (1987) Fundamental concepts in aquifer vulnerability, pollution risk and protection strategy. In: Waegeningh HG, van WV (eds) The Hague. Vulnerability of soil and groundwater to pollutants 38:69–86
Foster SSD (1988) Groundwater recharge and pollution vulnerability of British aquifers: a critical overview. Geological Society Special Publication 130 London
Freeze R, Cherry A (1979) Groundwater. Prentice-Hall, Englewood I Cliffs, N.]. USA 12(1987):145–165
Fritch TG, McKnight CL, Yelderman JC Jr, Arnold JG (2000) An aquifer vulnerability assessment of the Paluxy aquifer, central Texas, USA, using GIS and a modified DRASTIC approach. Environ Manag 25(3):337–345
Ghosh A, Tiwari AK, Das S (2015) A GIS based DRASTIC model for assessing groundwater vulnerability of Katri Watershed, Dhanbad, India. Model Earth Syst Environ 1(3):1–14
Goldscheider N, Klute M, Sturm S, Hotzl H (2000) The PI method: a GIS-based approach to mapping groundwater vulnerability with special consideration of karst aquifers. Z Angew Geol 463:157–166
Ground Water Resource Estimation Methodology (1997) Report of the Ground Water Resource Estimation Committee. Ministry of Water Resources Government of India, New Delhi
Ground Water Resource Estimation Methodology (2009) Report of the Ground Water Resource Estimation Committee. Ministry of Water Resources. Government of India, New Delhi
Jha MK, Sebastian J (2005) Vulnerability study of pollution upon shallow groundwater using drastic/GIS. In A paper presented in the 8th Annual International Conference and Exhibition in India, Map India. Geomatics, New Delhi, India
Kabera T, Zhaohui L (2008) A GIS based DRASTIC model for assessing groundwater in shallow aquifer in Yuncheng Basin, Shanxi, China. Res J Appl Sci 3(3):195–205
Krishna R, Iqbal J, Gorai AK, Pathak G, Tuluri F, Tchounwou PB (2014) Groundwater vulnerability to pollution mapping of Ranchi district using GIS. Appl Water Sci:1–14
Magiera P (2000) Methoden zur Absch tzung der Verschmutzungsempfindlichkeit des Grundwassers [Methods of assessing groundwater vulnerability]. Grundwasser 3:103–114
Mahato MK, Singh PK, Tiwari AK (2014) Evaluation of metals in mine water and assessment of heavy metal pollution index of East Bokaro Coalfield area, Jharkhand, India. Int J Earth Sci Eng 7(04):1611–1618
Margat J (1968) Vulnerabilite des mappes d’eau souterraine a la pollution. BRGM Publication, Orleans
Mondal GC, Singh AK, Singh TB, Singh S, Singh KK, Tewary BK (2009) Assessment of air quality in and around West-Bokaro coalfield, Hazaribag. Indian J Environ Prot 29(7):577–591
Nasri N, Chebil M, Guellouz L, Bouhlila R, Maslouhi A, Ibnoussina M (2014) Modelling nonpoint source pollution by nitrate of soil in the Mateur plain, northeast of Tunisia. Arab J Geosci 8(2):1057–1075
National Research Council (1993) Groundwater vulnerability assessment, contamination potential under conditions of uncertainty. National Academy Press, Washington, DC, 210 pp. Accessed December 2000 at: /http://books.nap.edu/books/0309047994/htmlS
Neves O, Matias MJ (2008) Assessment of groundwater quality and contamination problems ascribed to an abandoned uranium mine (Cunha Baixa region, Central Portugal). Environ Geol 53(8):1799–1810
Olıas M, Nieto JM, Sarmiento AM, Cerón JC, Cánovas CR (2004) Seasonal water quality variations in a river affected by acid mine drainage: the Odiel River (South West Spain). Sci Total Environ 333(1):267–281
Panagopoulos GP, Bathrellos GD, Skilodimou HD, Martsouka FA (2012) Mapping urban water demands using multi-criteria analysis and GIS. Water Resour Manag 26(5):1347–1363
Papadopoulou-Vrynioti K, Alexakis D, Bathrellos GD, Skilodimou HD, Vryniotis D, Vassiliades E (2014) Environmental research and evaluation of agricultural soil of the Arta plain, western Hellas. J Geochem Explor 136:84–92
Papadopoulou-Vrynioti K, Alexakis D, Bathrellos GD, Skilodimou HD, Vryniotis D, Vassiliades E, Gamvroula D (2013) Distribution of trace elements in stream sediments of Arta plain (western Hellas): the influence of geomorphological parameters. J Geochem Explor 134:17–26
Pathak DR, Hiratsuka A, Awata I, Chen L (2009) Groundwater vulnerability assessment in shallow aquifer of Kathmandu Valley using GIS-based DRASTIC model. Environ Geol 57(7):1569–1578
Pradhan SP, Vishal V, Singh TN, Singh VK (2014) Optimization of dump slope geometry vis-a`-visflyash utilization using numerical simulation. Am J Min Metall 2(1):1–7
Prasad RK, Singh VS, Krishnamacharyulu SKG, Banerjee P (2011) Application of drastic model and GIS: for assessing vulnerability in hard rock granitic aquifer. Environ Monit Assess 176(1–4):143–155
Rahman A (2008) A GIS based model for assessing groundwater vulnerability in shallow aquifer in Algarh, India. Appl Geogr 28(1):32–53
Saha D, Alam F (2014) Groundwater vulnerability assessment using DRASTIC and Pesticide DRASTIC models in intense agriculture area of the Gangetic plains, India. Environ Monit Assess 186(12):8741–8763
Samey AA, Gang C (2008) A GIS based DRASTIC model for the assessment of groundwater vulnerability to pollution in West Mitidja: Blida City, Algeria. J Appl Sci 3(7):500–507
Sener E, Sener S, Davraz A (2009) Assessment of aquifer vulnerability based on GIS and DRASTIC methods: a case study of the Senirkent-Uluborlu Basin (Isparta, Turkey). Hydro J 17(8):2023–2035
Shirazi SM, Imran HM, Akib S, Yusop Z, Harun ZB (2013) Groundwater vulnerability assessment in the Melaka State of Malaysia using DRASTIC and GIS techniques. Environ Earth Sci 70(5):2293–2304
Singh AK, Mahato M, Neogi B, Singh KK (2010) Quality assessment of mine water in the Raniganj coalfield area, India. Mine Water Environ 29:248–262
Singh AK, Mahato MK, Neogi B, Mondal GC, Singh TB (2011) Hydrogeochemistry, elemental flux, and quality assessment of mine water in the Pootkee-Balihari mining area, Jharia coalfield, India. Mine Water Environ 30(3):197–207
Singh AK, Mondal GC, Kumar S, Singh TB, Tewary BK, Sinha A (2008) Major ion chemistry, weathering processes and water quality assessment in upper catchment of Damodar River basin, India. Environ Geol 54:745–758
SNIFFER (Scotland and Northern Ireland Forum for Environmental Research) (2004) Development of a groundwater vulnerability screening methodology for the water framework directive. Project report code WFD 28, September 2004, Edinburgh
Tiwari AK, De Maio M, Singh PK, Singh AK (2016a) Hydrogeochemical characterization and groundwater quality assessment in a coal mining area, India. Arabian J Geosci 9(3):1–17. doi:10.1007/s12517-015-2209-5
Tiwari AK, Singh PK, Singh AK, De Maio M (2016b) Estimation of heavy metal contamination in groundwater and development of a heavy metal pollution index by using GIS technique. Bull Environ Contam Toxicol 96:508–515. doi:10.1007/s00128-016-1750-6
Tiwari AK, Singh PK, Mahato MK (2016c) Environmental geochemistry and a quality assessment of mine water of the West Bokaro Coalfield, India. Mine Water Environ. doi:10.1007/s10230-015-0382-0
Tiwary RK (2001) Environmental impact of coal mining on water regime and its management. Water Air Soil Pollut 132:185–199
Tripathy DP (2010) Determination of trace elements concentration and trace elements index in mine water in some fire and non-fire affected areas of Jharia coalfield, India. Pollut Res 29:385–390
Trivedi R, Vishal V, Pradhan SP, Singh TN, Jhanwar JC (2012) Slope stability analysis in Limestone mines. Int J Earth Sci Eng 5(4):759–766
Umar R, Ahmed I, Alam F (2009) Mapping groundwater vulnerable zones using modified DRASTIC approach of an alluvial aquifer in parts of Central Ganga Plain, Western Uttar Pradesh. J Geo Soc India 73(2):193–201
Utom AU, Odoh BI, Egboka BC (2013) Assessment of hydrogeochemical characteristics of groundwater quality in the vicinity of Okpara coal and Obwetti fireclay mines, near Enugu town, Nigeria. Appl Water Sci 3(1):271–283
Vierhuff HW, Aust WH (1981) Die Grundwasservorkommen in der Bundesrepublik Deutschland. Geologisches Jahrbuch, Band C30:3–110
Vishal V, Pradhan SP, Singh TN (2010) Instability analysis of mine slope by finite element method approach. Int J Earth Sci Eng 3(6):11–23
Vrba J, Zaporozec A (1994) Guidebook on mapping groundwater vulnerability. Int Contrib Hydrogeol Nr. 16, Hannover
Yellishetty M, Ranjith PG, Kumar DL (2009) Metal concentrations and metal mobility in unsaturated mine wastes in mining areas of Goa, India. Reso Conser Recyc 53(7):379–385
Acknowledgments
The authors are grateful to Professor D. C. Panigarhi, Director, Indian School of Mines, for his kind support. We are thankful to Mr. Amit Ghosh, Project Assistant at Central Institute of Mining and Fuel Research, Dhanbad and Central Coalfield Limited (CCL), India. One of the authors (Ashwani Kumar Tiwari) is grateful to ISM/MHRD/Government of India and European Commission (Erasmus Mundus AREaS+ Program) for grant support. Our hearty thanks to the anonymous reviewer and Editor-in-Chief for his valuable suggestions to improve the study in the present form.
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Tiwari, A.K., Singh, P.K. & De Maio, M. Evaluation of aquifer vulnerability in a coal mining of India by using GIS-based DRASTIC model. Arab J Geosci 9, 438 (2016). https://doi.org/10.1007/s12517-016-2456-0
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DOI: https://doi.org/10.1007/s12517-016-2456-0