Abstract
Open pit mines are potential source of metal contamination. Three types of open pit mines, i.e. copper, quartzite and granite were selected to understand the mobility and behaviour of metals. Metal contamination due to abandoned open pit copper mines (Average Cu = 64.57 ± 90 µg/L) is observed more comparative to quartzite (Average Cu = 20.42 ± 34.39 µg/L) and granite mines (Average Cu = 9.67 ± 7.94 µg/L). Acid mine drainage (AMD) from copper mines result in dissolution of metals and contaminates groundwater in the downstream direction. Correlation used for source assessment confirms the influence of anthropogenic or abandoned pit mine on metal concentration in groundwater. It is observed that the impact of abandoned pit mine is more compared to tailings and overburden dumps. Dissolution and precipitation process control the metal abundance in downstream groundwater. Precipitation dominates dissolution process with distance and results in decrease in metal concentration. It also confirms the self-neutralisation and self-attenuation capacity of the aquifer. The study recommends restoration of abandoned open pit mines to their natural conditions to avoid metal contamination in downstream.
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References
Abdelshafy M, Saber M, Abdelhaleem A, Abdelrazek SM, Seleem EM (2019) Hydrogeochemical processes and evaluation of groundwater aquifer at Sohag city, Egypt. Sci Afr 6:e00196
Antunes IMHR, Gomes MEP, Neiva AMR, Carvalho PCS, Santos ACT (2016) Potential risk assessment in stream sediments, soils and waters after remediation in anabandoned W>Sn mine (NE Portugal). Ecotox Environ Safe 133:135–145
Ardejani FD, Shokri BJ, Bagheri M, Soleimani E (2010) Investigation of pyrite oxidation and acid mine drainage characterization associated with Razi active coal mine and coal washing waste dumps in the Azad shahr–Ramian region, northeast Iran. Environ Earth Sci 61:1547–1560
Baidya AS, Paul J, Pal DC, Upadhyay D (2017) Mode of occurrence and geochemistry of amphibole in the Kolihan-Chandmari copper deposits, Rajasthan, India: Insight into the ore-forming process. Ore Geol Rev 80:1092–1110
Bauer H, Schröckenfuchs TC, Decker K (2016) Hydrogeological properties of fault zones in a karstified carbonate aquifer (Northern Calcareous Alps, Austria). Hydrogeol J 24:1147–1170
Bigham JM, Nordstrom DK (2000) Iron and aluminium hydroxysulfates from acid sulphate waters. In: Alpers CN, Jambor JL, Nordstrom DK (eds) Reviews in mineralogy and geochemistry—sulfate minerals: crystallography, geochemistry, and environmental significance. The Mineralogical Society of America, Washington, pp 351–403
Bird KS, Navarre-Sitchler A, Singha K (2020) Hydrogeological controls of arsenic and uranium dissolution into groundwater of the Pine Ridge Reservation, South Dakota. Appl Geochem 114:104522
Cánovas CR, Macías F, Pérez-López R (2016) Metal and acidity fluxes controlled by precipitation/dissolution cycles of sulfate salts in an anthropogenic mine aquifer. J Contam Hydrol 188:29–43
Central Groundwater Board (2008) Groundwater brochure for Jhunjhunu district, Rajasthan. Government of India, pp 7–11
Central Ground Water Board (CGWB) (2017) Report on “Aquifer mapping and ground after management” Jhunjhunu District, Rajasthan. Ministry of Water Resources, River Development and Ganga Rejuvenation, Government of India
Chang CL (2009) The impact of watershed delineation on hydrology and water quality simulation. Environ Monit Assess 148:159–165
Chen ZS, Lee GJ, Liu JC (2000) The effects of chemical remediation treatments on the extractability and speciation of cadmium and lead in contaminated soils. Chemosphere 41:235–242
Chiamsathit C, Auttamana S, Thammarakcharoen S (2020) Heavy metal pollution index for assessment of seasonal groundwater supply quality in hillside area, Kalasin, Thailand. Appl Water Sci 10:142
Cidu R, Biagini C, Fanfani L, La Ruffa G, Marras I (2001) Mine closure at Monteponi (Italy): effect of the cessation of dewatering on the quality of shallow groundwater. Appl Geochem 16:489–502
Cidu R, Frau F, Da Pelo S (2011) Drainage at abandoned mine sites: natural attenuation of contaminants in different seasons. Mine Water Environ 30:113–126
Dan-Badjo AT, Ibrahim OZ, Guéro Y, Morel JL, Feidt C, Echevarria G (2019) Impacts of artisanal gold mining on soil, water and plant contamination by trace elements at Komabangou. West Niger J Geochem Explor 205:106328
Dasgupta SP (1968) The structural history of the Khetri Copper Belt, Jhunjhunu and Sikar districts. Rajasthan. Geol Survey India 98:170
Díaz-Puga MA, Pulido-Bosch A, Vallejos A, Sola F, Daniele L, Simón M, García I (2020) Impact of mine leachates on a carbonate aquifer (SE Spain). Mine Water Environ. https://doi.org/10.1007/s10230-020-00703-9
Elouear Z, Bouhamed F, Boujelben N, Bouzid J (2016) Assessment of toxic metals dispersed from improperly disposed tailing, Jebel Ressas mine. NE Tunisia Environ Earth Sci 75:254
Fu F, Wang Q (2011) Removal of heavy metal ions from wastewaters: a review. J Environ Manage 92(3):407–418
Gandy CJ, Younger PL (2007) Predicting Groundwater rebound in the South Yorkshire Coalfield, UK. Mine Water Environ 26:70–78
Gaofeng Z, Yonghong S, Chunlin H, Qi F, Zhiguang L (2010) Hydrogeochemical processes in the groundwater environment of Heihe River Basin, northwest China. Environ Earth Sci 60:139–153
González RM, Cánovas CR, Olías M, Macías F (2020) Seasonal variability of extremely metal rich acid mine drainages from the Tharsis mines (SW Spain). Environ Pollut 259:113829
Gupta P, Guha DB, Chattopadhyay B (1998) Basement–cover relationship in the Khetri Copper Belt and the emplacement mechanism of the granite massifs, Rajasthan. J Geol Society India 52:417–432
Han YS, Gallegos TJ, Demond AH, Hayes KF (2011) Fes-coated sand for removal of arsenic(Iii) under anaerobic conditions in permeable reactive barriers. Water Res 45:593–604
Hermann R, Neumann-Mahlkau P (1985) The mobility of zinc, cadmium, copper, lead, iron and arsenic in ground water as a function of redox potential and pH. Sci Total Environ 43(1–2):1–12
Hodgkinson D, Benabderrahmane H, Elert M, Hautojärvi A, Selroos J-O, Tanaka Y, Uchida M (2009) An overview of Task 6 of the Äspö Task Force: modelling groundwater and solute transport: improved understanding of radionuclide transport in fractured rock. Hydrogeol J 17:1035–1049
Ibrahim RGM, Korany EA, Tempel RN, Gomaa MA (2019) Processes of water–rock interactions and their impacts upon the groundwater composition in Assiut area, Egypt: applications of hydrogeochemical and multivariate analysis. J Afr Earth Sci 149:72–83
Imai N, Terashima S, Itoh S, Ando A (1995) Compilation of analytical data for minor and trace elements in seventeen GSJ geochemical reference samples, “igneous rock series”. Geostand Newsl 19(2):135–213
Kaur P, Zeh A, Okrusch M, Chaudhri N, Gerdes A, Brätz H (2016) Separating regional metamorphic and metasomatic assemblages and events in the northern Khetri complex, NW India: evidence from mineralogy, whole-rock geochemistry and U-Pb monazite chronology. J Asian Earth Sci 129:117–141
Knight J, Lowe J, Joy S, Cameron J, Merrillees J, Nag S, Shah N, Dua G, Jhala K (2002) The Khetri Copper Belt, Rajasthan: iron oxide copper-gold terrane in the Proterozoic of NW India. In: Porter TM (ed) Hydrothermal Iron Oxide Copper-Gold and related deposits: a global perspective, vol 2. PGC Publishing, Adelaide, pp 321–341
Kovács E, Tamás J, Frančišković-Bilinski S, Omanović D, Bilinski H, Pižeta I (2012) Geochemical study of surface water and sediment at the abandoned Pb-Zn mining site at Gyöngyösoroszi. Hung Fresenius Environ Bullet 21(5a):1212–1218
Leppӓnen JJ, Luoto TP, Weckstrӧm J (2019) Spatio-temporal impact of salinated mine water on Lake Jormasjӓrvi, Finland. Environ Pollut 247:1078–1088
Lianchong L, Tianhong Y, Zhengzhao L, Wancheng Z, Chunan T (2011) Numerical investigation of groundwater outbursts near faults in underground coal mines. Int J Coal Geol 85:276–288
Liang Z, Ren T, Ningbo W (2017) Groundwater impact of open cut coal mine and an assessment methodology: a case study in NSW. Int J Min Sci Technol 27:861–866
Lu Y, Wang L (2015) Numerical simulation of mining-induced fracture evolution and water flow in coal seam floor above a confined aquifer. Comput Geotech 67:157–171
Macías F, Caraballo MA, Rötting TS, Pérez-López R, Nieto JM, Ayora C (2012) From highly polluted Zn-rich acid mine drainage to non-metallic waters: implementation of a multi-step alkaline passive treatment system to remediate metal pollution. Sci Total Environ 433:323–330
Mahaqi A, Moheghy MA, Moheghi MM, Mehiqi M, Zandvakili Z (2020) Environmental hydrogeochemistry characteristics, controlling factors and groundwater quality assessment in Herat City, West Afghanistan. Water Resour 47:325–335
Małecki JJ, Kadzikiewicz-Schoeneich M, Eckstein Y, Szostakiewicz-Hołownia M, Gruszczyński T (2017) Mobility of copper and zinc in near-surface groundwater as a function of the hypergenic zone lithology at the Kampinos National Park (Central Poland). Environ Earth Sci 76:276
Mansour K, Omar K, Ali K, Zaher MA (2018) Geophysical characterization of the role of fault and fracture systems for recharging groundwater aquifers from surface water of Lake Nasser. NRIAG J Astron Geophys 7(1):99–106
Martin A, Landesman C, Lépinay A, Roux C, Champion J, Chardon P, Montavon G (2019) Flow period influence on uranium and trace elements release in water from the waste rock pile of the former La Commanderie uranium mine (France). J Environ Radioact 208–209:106010
Mishra M, Singh S, Das T, Kar RN, Rao KS, Sukla LB, Mishra BK (2008) Bio-dissolution of copper from Khetri lagoon material by adapted strain of Acidithiobacillus ferrooxidans. Korean J Chem Eng 25(3):531–534
Moyé J, Picard-Lesteven T, Zouhri L, El Amari K, Hibti M, Benkaddour A (2017) Groundwater assessment and environmental impact in the abandoned mine of Kettara (Morocco). Environ Pollut 231:899–907
Naha K, Mukhopadhyay DK, Mohanty R (1988) Structural evolution of the rocks of the Delhi Group around Khetri, northeastern Rajasthan. In: Roy AB (Eds.), Precambrian of the Aravalli Mountain, Rajasthan, India, Mem Geol Soc India 7:207–245
Neiva AMR, Carvalho PCS, Antunes IMHR, Albuquerque MTD, Santos ACS, Cunha PP, Henriques SBA (2019) Assessment of metal and metalloid contamination in the waters and stream sediments around the abandoned uranium mine area from Mortórios, central Portugal. J Geochem Explor 202:35–48
Newman CP, Poulson SR, McCrea KW (2020) Contaminant generation and transport from mine pit lake to perennial stream system: multidisciplinary investigations at the big ledge mine. Geochemistry, Nevada. https://doi.org/10.1016/j.chemer.2019.125552
Nordstrom DK (2011) Mine waters: acidic to circumneutral. Elements 7:393–398
Nyirenda TM, Zhou J, Mapoma HWT, Xie L, Li Y (2016) Hydrogeochemical characteristics of groundwater at the Xikuangshan antimony mine in South China. Mine Water Environ 35:86–93
Olías M, Cánovas CR, Basallote MD, Macías F, Pérez-López R, González RM, Millán-Becerro R, Nieto JM (2019) Causes and impacts of a mine water spill from an acidic pit lake (Iberian Pyrite Belt). Environ Pollut 250:127–136
Omanović D, Pižeta I, Vukosav P, Kovács E, Frančišković-Bilinski S, Tamás J (2015) Assessing element distribution and speciation in a stream at abandoned Pb-Zn mining site by combining classical, in-situ DGT and modelling approaches. Sci Total Environ 511:423–434
Opitz J, Alte M, Bauer M, Schäfer W, Söll T (2020) Estimation of self-neutralisation rates in a lignite Pit Lake. Mine Water Environ 39:556–571
Punia A, Siddaiah NS (2017) Assessment of heavy metal contamination in groundwater of Khetri copper mine region, India and health risk assessment. Asian J Water Environ Poll 14(4):9–19
Punia A, Siddaiah NS (2019) Mobility and behaviour of heavy metals in copper mine tailings and neighboring soil at Khetri. India Mine Water Environ 38(2):385–390
Punia A, Siddaiah NS, Singh SK (2017) Source and assessment of heavy metal pollution at Khetri copper mine tailings and surrounding soil, Rajasthan, India. Bull Environ Contam Toxicol 99:633–641
Radojevic M, Bashkin VN (1999) Practical environmental analysis. Royal Society of Chemistry, pp 154–155
Rathi MS, Khanna PP, Mukherjee PK, Purohit KK, Saini NK (1994) Working values for major and trace elements for metabasic reference sample (MBH). J Geol Soc India 43(3):295–303
Ray SK (1990) The albitite line of northern Rajasthan– A fossil intracontinental rift zone. J Geo Society India 36:413–23
Richards LA, Casanueva-Marenco MJ, Magnone D, Sovann C, van Dongen BE, Polya DA (2019) Contrasting sorption behaviours affecting groundwater arsenic concentration in Kandal Province, Cambodia. Geosci Front 10:1701–1713
Roychowdhury MK, Dasgupta SP (1964) On the geology and mineralization in the Khetri copper belt, Jhnujhunu and Sikar districts, Rajasthan. Geol Sur India 31:188–198
Roy Chowdhury MK, Das Gupta SP (1965) Ore-localization in the Khetri copper belt, Rajasthan, India. Econ Geol 60:69–88
Royer-Lavallée A, Neculita CM, Coudert L (2020) Removal and potential recovery of rare earth elements from mine water. J Ind Eng Chem 89:47–57
Saini NK, Khanna PP, Mukherjee PK, Purohit KK (2013) Preparation and characterisation of two geochemical reference materials: DG-H (granite) and AM-H (amphibolite) from the Himalayan orogenic belt. Geostand Geoanal Res 38:111–122
Sappa G, Ergul S, Ferranti F (2014) Geochemical modeling and multivariate statistical evaluation of trace elements in arsenic contaminated groundwater systems of Viterbo Area, (Central Italy). SpringerPlus 3:1–19
Sarkar SC, Dasgupta S (1980) Geologic setting, genesis and transformation of sulfide deposits in the northern part of Khetri copper belt, Rajasthan, India—an outline. Min Deposita 15:117–137
Scibek J (2020) Multidisciplinary database of permeability of fault zones and surrounding protolith rocks at world-wide sites. Sci Data 7:95
Singhal BBS, Gupta RP (1999) Fractures and discontinuities. Applied hydrogeology of fractured rocks. Springer, Dordrecht, pp 13–35
Smith M, Roychoudhury AN (2013) Mobilisation of Iron from rocks in a fractured aquifer: Lithological and geochemical controls. Appl Geochem 31:171–186
Sun Q, Cui P-X, Fan T-T, Wu S, Zhu M, Alves ME, Zhou D-M, Wang Y-J (2018) Effects of Fe(II) on Cd(II) immobilization by Mn(III)-rich δ-MnO2. Chem Eng J 353:167–175
Valenzuela-Diaz MJ, Navarrete-Calvo A, Caraballo MA, McPhee J, Garcia A, Correa-Burrows JP, Navarro-Valdivia L (2020) Hydrogeochemical and environmental water quality standards in the overlap between high mountainous natural protected areas and copper mining activities (Mapocho river upper basin, Santiago, Chile). J Hydrol 588:125063
Verma S, Mukherjee A, Mahanta C, Choudhury R, Badoni RP, Joshi G (2019) Arsenic fate in the Brahmaputra river basin aquifers: controls of geogenic processes, provenance and water-rock interactions. Appl Geochem 107:171–186
Wang Q, Dong S, Wang H, Yang J, Huang H, Dong X, Yu B (2020) Hydrogeochemical processes and groundwater quality assessment for different aquifers in the Caojiatan coal mine of Ordos Basin, northwestern China. Environ Earth Sci 79:199
Wilkin RT (2008) Contaminant attenuation processes at mine sites. Mine Water Environ 27:251–258
Yang Q, Li Z, Ma H, Wang L, Martín JD (2016) Identification of the hydrogeochemical processes and assessment of groundwater quality using classic integrated geochemical methods in the Southeastern part of Ordos basin, China. Environ Pollut 218:879–888
Yang Z, Liu C, Zhu H, Xie F, Dou L, Chen J (2019) Mechanism of rock burst caused by fracture of key strata during irregular working face mining and its prevention methods. Int J Min Sci Technol 29:889–897
Yao W, Yang Z, Guo X (2019) Fracture development in large-scale overburden strata induced by longwall mining. Energ Sources Part Recov Util Environ Eff 41(3):269–279
Yin S, Zhang J, Liu D (2015) A study of mine water inrushes by measurements of in situ stress and rock failures. Nat Hazards 79:1961–1979
Zhang H, Huang GH, Wang D (2013) Establishment of channel networks in a digital elevation model of the prairie region through hydrological correction and geomorphological assessment. Can Water Resour J 38(1):12–23
Zhu G, Wu X, Ge J, Liu F, Zhao W, Wu C (2020) Influence of mining activities on groundwater hydrochemistry and heavy metal migration using a self-organizing map (SOM). J Cleaner Prod 257:120664
Acknowledgements
The postdoctoral fellowship of the Indian Institute of Technology Guwahati is acknowledged. The authors also acknowledge the support of IUAC for extending the XRF/ICPMS established under the National Geochronology Facility funded by the Ministry of Earth Sciences (MoES), Govt. of India with reference number MoES/P.O.(Seismic)8(09)-Geochron/2012. The authors also acknowledge the help of Dr. Sumaya Prasad Dhal (Research Associate), IUAC in the handling of the instrument.
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Punia, A., Bharti, R. & Kumar, P. Impact of mine pit lake on metal mobility in groundwater. Environ Earth Sci 80, 245 (2021). https://doi.org/10.1007/s12665-021-09559-w
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DOI: https://doi.org/10.1007/s12665-021-09559-w