Gold Mineralisation and their Lithological Controls at Nagavi Area, Gadag Schist Belt, in Karnataka, India
DOI:
https://doi.org/10.18311/jmmf/2024/44558Keywords:
Gadag Schist Belt, Geological Structures, Gold Mineralization, Lithological control, Nagavi AreaAbstract
Dharwar craton is located in southern India is part of the Dharwar-Singhbhum proto-continent and is known for its complex tectonic and structural controls. It’s made up of two distinct parts, Western Dharwar Craton (WDC) and the Eastern Dharwar Craton (EDC) house several schist belts. Many of these schist belts, such as the Kolar schist belt, Hutti schist belt, Chitradurga schist belt and the Gadag schist belt, are auriferous. In such schist belts, gold occurs in association with sulphides such as pyrite, pyrrhotite, arsenopyrite and chalcopyrite. Gold mineralization in these belts is found to occur in different lithologies. The Gadag schist belt is composed dominantly of metabasalt in its western half and meta sediments in the eastern half. Quartz-carbonate veins are observed to cut across these lithologies as well as the Banded Iron Formations (BIFs). This paper aimed to study the gold mineralization in different lithologies of the Gadag schist belt and found that metabasalts and BIFs are the dominant rocks hosting gold. It is also observed that mineralization is strata-bound. Most of the places’ auriferous sheared zones were observed in the study area. In Nagavi area, BIF hosted gold mineralization is observed, and major gold concentration varies from <21 to <26 ppb (parts per billion). Pyrite occurs as characteristic cubic crystals and as clusters of small grains. In carbonated sheared anorthosite, the rock is fine to medium-grained and in-equigranular. It consists of simple to polysynthetically twinned subhedral (100-200 by 400-600 μm) laths (~40-45%) set in a groundmass of irregular anhedral grains of secondary carbonate (~35-40%), chlorite (~8-10%), opaque (~5-7%) and accessory epidote and quartz.
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This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Accepted 2024-08-29
Published 2024-09-27
References
Hammond NQ, Moore JM. Archaean lode gold mineralization in banded iron formation at the Kalahari goldridge deposit, Kraaipan greenstone belt, South Africa. Mineralium Deposita. 2006; 41:483-503. https:// doi.org/10.1007/s00126-006-0074-6.
Puranik SC. Primary Sedimentary Structures in Banded Iron Formations from Gadag Schist Belt Karnataka, India. Int J Earth Sci Eng. 2011; (4)2:111-21.
Ugarkar AG, Panaskar DB, Ranganath G. Geochemistry, petrogenesis and tectonic setting of metavolcanics and their implications for gold mineralization in gadag gold field, Southern India. Gondwana Research. 2000; 3(3):371-84. https://doi.org/10.1016/S1342937X(05)70295-1.
Ram MM, Sarma DS, Charan SN, Balaram V, Rajasekhar VB, Ahmad T. Geochemistry and petrogenesis of amphibolite’s from the southern part of Gadag greenstone belt, Karnataka. J Geol Soc India. 2008; 72:484-94.
Chandrashekharappa A, Basavanna M, Lakkundi TK. Geochemistry of banded iron formations and associated gold mineralization of Nagavi, Gadag schist belt, Karnataka. Int J Earth Sci Eng. 2015; 08(4):1880-6.
Chandrashekharappa A, Kantharaja DC, Lakkundi TK. A study of primary sedimentary structures in Banded Iron Formations (BIFs) of Nagavi area, Gadag schist belt, Karnataka, India. J Mines Met Fuels. 2021; 69(11).
Chandrashekharappa A, Deepak MS, Lakkundi TK, Kumar VGA. An integrated study of landsat ETM and cartosat DEM data in identification of Banded Iron Formations (BIFs) associated with sulphide mineralization. Acta Geodyn Geomater. 2022; 19(1):35-44. https://doi.org/10.13168/AGG.2021.0041.
Chakabarti S, Reddy US, Natarajan WK. Sedimentary structures in the Archaean sediments of Gadag schist belt, Karnataka. J Geol Soc India. 1993; 41:523-8.
Chakabarti S, Devraju U. Sedimentary structures in the Archaean sediments of Gadag schist belt, Karnataka. J Geol Soc India. 1994; 41:523-8.
Radhakrishna BP, Vaidyanadhan R. Geology of Karnataka. Geol Soc India; 1997. p. 354.
Chadwick B, Vasudev VN, Nazeer A. The Sandur schist belt and its adjacent plutonic rocks have implications for late archaean crustal evolution in Karnataka. J Geol Soc India. 1996; 47:37-57.
Chandrashekharappa A, Basavanna M, Lakkundi TK. Textural and fluid inclusions studies on Banded Iron Formations (BIFs) hosted gold mineralisation in the Nagavi area, Gadag schist belt, Dharwar Craton. Int J Earth Sci Eng. 2014; 7(4):1593-600.
Naqvi SM. The Sandur schist belt and its adjacent plutonic rocks: Implications of late Archean crustal evolution in Karnataka. J Geol Soc India. 1997; 49(4):459-60.
Groves DI. The crustal continuum model for lateArchaean lode-gold deposits of the Yilgarn Block, Western Australia. Miner Depos. 1993; 28:366- 74. https://doi.org/10.1007/BF02431596.
Bhaskar YJR, Sivaraman TV, Pantulu GVC, Gopalan K, Naqvi SM. Rb-Sr ages of late Archaean metavolcanics and granites, Dharwar craton, South India, and evidence for early Proterozoic thermotactic events. Precambrian Res. 1992; 59:145-70. https://doi.org/10.1016/0301-9268(92)90055-S.
Fripp REP. Strata-bound gold deposits in Archaean banded iron fomation, Rhodesia. Econ Geol. 1976; 71:58-75. https://doi.org/10.2113/gsecongeo.71.1.58.
Phillips GN, Groves DI, Martyn JE. An epigenetic origin for Archean banded iron formationhosted gold deposits. Econ Geol. 1984; 79:162- 71. https://doi.org/10.2113/gsecongeo.79.1.162.
Vielreicher RM, Groves DI, Ridley NJ, McNaughton NJ. A replacement origin for the BIF-hosted gold deposit at Mt. Morgans, Yilgarn Block, W.A. Ore Geol Rev. 1994; 9:325-47. https://doi.org/10.1016/0169-1368(94)90003-5.
Lhotka PG, Nesbitt BE. Geology of unmineralized and gold bearing iron formation, Contwoyto Lake Point Lake region, Northwest Territories, Canada. Can J Earth Sci. 1989; 26:46-64. https://doi.org/10.1139/e89-005.
Pretorius AI, Van RDD, Barton JM Jr. BIF-hosted gold mineralization at the Fumani Mine, Sutherland greenstone belt, South Africa. S Afr J Geol. 1988; 91:42938.
Cathelineau M, Marie CB, Phillip H, Phillippe M, Michael D. Gold in arsenopyrites, crystal chemistry, location and state, physical and chemical conditions of deposition. Econ Geol. 1988; 6:328-341. https://doi.org/10.5382/ Mono.06.25.
Saager R, Oberthür T, Tomschi H. Geochemistry, and mineralogy of Banded Iron Formation - hosted gold mineralization in the Gwanda Greenstone Belt, Zimbabwe. Econ Geol. 1987; 82:2017-32. https://doi.org/10.2113/gsecongeo.82.8.2017.
Brown PE, Lamb WM. P-V-T properties of fluids in the system H2O-CO2-NaCl: New graphical presentation and implications for fluid inclusion studies. Geochim Cosmochim. Acta. 1988; 53:1209-21. https://doi.org/10.1016/0016-7037(89)90057-4.
Beeraiah MB, Sengupta S, Venkateswamy RTV. Exploration for gold in sulphidic banded magnetite chert of Nagavi-Mallasamudra area, Gadag schist belt. Geological Survey of India. 2001; 58:339-43.
Gilligang JM, Foster RP. Gold mineralisation in ironformation: the importance of contrasting modes of deformation at the Lennox mine, Zimbabwe. In: African Mining, Inst. of Mining and Metallurgy, London; 1987. p. 127-138.