Abstract
Polymetallic sulfide ores (Zn, Pb, Fe, Cu, Ag, and Cd) found in the Alanish locality of northern Iraq are hosted by dolostone in the Late Permian Chia Zairi Formation. The Alanish locality is one of several Zn–Pb deposits that are widespread in northern Iraq, situated along the northern passive margin of the Arabian plate. This paper describes the ore deposit classification, mineral chemistry, and paragenetic sequence of the area and proposes an ore formation model. We report the presence of acanthite and greenockite for the first time in Iraq. A brine solution derived from the sedimentary basin formed the primary sulfide ore minerals (sphalerite, galena, acanthite, pyrite, chalcopyrite, greenockite, and marcasite). The pre-tectonic mineralization is characterized by replacement textures including (1) high-Fe, low-Zn, dark-colored, coarse-grained sphalerite; (2) deformed anisotropic coarse-grained galena; and, (3) idiomorphic cubes of crushed pyrite. Conversely, the post-tectonic mineralization is characterized by open-space filling textures, including (1) low-Fe, high-Zn, light-colored, fine aggregated sphalerite; (2) fine-grained galena; and, (3) the existence of acanthite and marcasite. Although galena is an Ag carrier, both mineralization phases contained non-argentiferous galena. Non-sulfides (smithsonite, cerussite, and goethite) have replaced older sulfides in many areas due to supergene process. Gangue minerals present are dolomite, calcite, barite, and siderite. Open spaces and cavity filling of small paleo-karsts, replacement, veins, and veinlets are common features of the ore body. Metals were sourced from brines generated in the sedimentary basin, whereas sulfur was derived from nearby evaporates. Sediment compaction and tectonic activity, probably during Late Cretaceous, were the driving forces that squeezed and moved ore-bearing fluids derived from the sedimentary basin. Multiple stages of ore-bearing fluids were epigenetically intruded into the Late Paleozoic dolostone, forming an epigenetic strata-bound Mississippi Valley-type deposit precipitated under a temperature of 120 °C, as indicated by the cadmium fractionation in sphalerite and galena. Dolomitization and tectonic activity provided the necessary permeability for accumulating ores. The main ore body is directly connected to a fault plane and to adjacent dolostone that is frequently fractured and brecciated.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Al-Bassam KS (2013) Mineral resources of Kurdistan region, Iraq. Iraqi Bull Geol Mining 9(3):103–127
Al-Bassam KS, Hak J, Watkinson D (1982) Contribution to the origin of the Serguza lead-zinc pyrite deposit, North Iraq. Mineral Deposita 17:133–149
Al-Hadi AH (2007) Paleozoic stratigraphic lexicon and hydrocarbon habitat of Iraq. GeoArabia, Gulf PetroLink 12:63–130
Aqrawi AA, Al-Hadidy AH, Horbury AD (2013) Permo-triassic sequence of the Arabian Plate. In: Michael Pöppelreiter (ed). Special Publication of EAGE, Chapter 9, pp 199–218
Awadh SM, Habib RH, Al-Bassam KS (2008a) Mineralogy, geochemistry and origin of zinc-lead-barite deposits in northern thrust zone, northern Iraq. Iraqi J Sci 49(2):119–131
Awadh SM, Habib RH, Al-Bassam KS (2008b) Genesis of the zinc-lead-barite deposits in northern Iraq: ore mineralogy, geochemisty fluid inclusions lead isotopes and sulfur isotopes imlpications, Dirasat. Pure Sci 35(2):960109
Barton PA, Bethke PM (1987) Chalcopyrite disease in sphalerite: pathology and epidemiology. Am Mineral 72:451–468
Berra F, Angiolini L (2014) The evolution of the tethys region throughout the phanerozoic: a brief tectonic reconstruction. In: Marlow L, Kendall C, Yose L (eds) Petroleum systems of the Tethyan region, AAPG Memoir 106, pp. 1–27
Best JA, Barazangi M, Al-Saad D, Sawaf T, Gebran A (1993) Continental margin evolution of the northern Arabian platform in Syria. Am Assoc Pet Geol Bull 77(2):173–193
Bethke PM, Barton PB (1971) Distribution of some minor elements between coexisting sulfide minerals. Econ Geol 66:140–163
Bozkurt E, Mittwede SK (2001) Introduction to the geology of Turkey, a synthesis. Int Geol Rev 43:578–594
Bradley DC, Leach DL (2003) Tectonic controls of Mississippi Valley-type lead-zinc mineralization in orogenic forelands. Mineral Deposita 38:652–667
Bradley DC, Leach DL, Symons D, Emsbo P, Premo W, Breit G, Sangster DF (2004) Reply to discussion on “tectonic controls of Mississippi Valley-type le; id-zinc mineralization in orogenic forelands” by S. E. Kesler, I. T Chesley, I. N. Christenscn, R. D. Hagni, W. Heijlen, J. R. Kyle, K. C. Misra, R Muchez, and R. Van der Voo. Mineral Deposita 39:515–519
Braithwaite CJR, Rizzi G (1997) The geometry and petrogenesis of hydrothermal dolomites at Navan, Ireland. Sedimentology 44:421–440
Bruhwiler D, Seitert R, Calzaferri G (1999) Quantum-size silver sulfide clusters in zeolite a. J Phys Chem 103(31):6397–6399
Buday T (1980) The Regional Geology of Iraq, stratigraphy and paleogeography. In: Kassab, I. M. and Jassim, S. Z. (eds), vol. 1, Geol. Surv. and Miner. Invest. Baghdad, Iraq, 445p
Cabri LJ (1987) The mineralogy of precious metals: new developments and metallurgical implications. Can Mineral 25:l–7
Cabri LJ (1992) The distribution of trace precious metals in minerals and mineral products: the 23rd Hallimond lecture (1991). Mineral Mag 56:289–308
Cook NJ, Ciobanu CL, Pring A, Skinner W, Shimizu M, Danyushevsky L, Saini- Eidukat B, Melcher F (2009) Trace andminor elements in sphalerite: a LA-ICPMS study. Geochim Cosmochim Acta 73:4761–4791
Craig JR, Vaughan DJ (1981) Ore microscopy and ore petrography. John Wiley and Sons, New York, p. 406
Dorfmann W (1974) Der Bergbau im Raume Klausen. Dissertation, PhD Thesis, University of Padua, Padua, 146p
Dunnington VH, Wetsel R, Morton DM (1959) Mesozoic and Plaeozoic. In: Van Bellen RC, Dunnington HV, Wetzel R and Morton DM (eds) Lexique Stratigraphique I International III Asie. International Geological Congress Commission on Stratigraphy. Paris, pp 333
Einaudi MT, Meinert LD, Newberry RJ (1981) Skarn deposits, economic geology 75th anniversary. 317–391 pp
Gorecka E (1996) Mineral sequence development in the Zn-Pb deposits of the Silesian-Cracow area, Poland. Prace panstwowego Instytutu geologicznego CLV. Carbonate-hosted zinc and lead deposits in the Silesian-Cracow area. Poland, pp. 25–36
Grandia F, Cardellach E, Canals A, Banks DA (2003) Geochemistry of the fluids related to epigenetic carbonate-hosted Zn–Pb deposits in the Maestrat Basin, eastern Spain: fluid inclusion and isotope (Cl, C, O, S, Sr) evidence. Econ Geol 98:933–954
Gregg JM, Sibley DF (1984) Epigenetic dolomitization and the origin of xenotopic dolomite texture. Jour Sed Petrology 5:908–93I
Hak J, Watkinson D, Al-Bassam K (1983) The origin of the Marabasta base metal deposits, NE Iraq. Vestnik ustredniho ustavo geologickeho 58:141–150
Heyl AV, Agnew AF, Lyons EJ, Behre CH (1959) The geology of the Upper Mississippi Valley zinc-lead district. U.S. Geological Survey Professional Paper 424-D, 310 p
Hunt JM (1996) Petroleum geochemistry and geology. In: Freeman WH (ed). New York
Jassim SZ, Buda G, Neuzilova M, Suk M (1982) Metamorphic development of the Iraqi zagros ophiolite zone. Krystalinikum 16:21–40
Kesler SE, Chesley JT, Cbristensen IN, Hagni RD, Heijlen W, Kyle IR, Misra C, Muchez P, van der Voo R (2004) Discussion of “tectonic controls of Mississippi Valley-type lead-zinc mineralization in orogenic forelands” by Bradley DC and Ledch DL. Mineral Deposita 39:512–514
Koptagel O, Ulosoy U, Efe A (2005) A study of sulfur isotopes in determining the genesis of Gsynyk and Celaldauy Desandre Pb-Zn deposits. Eastern Yahyaly, Kayseri, Central Turkey. J Asian Earth Sci 25:279–289
Leach DL, Bradley DC, Lewchuck M, Symons DTA, Brannon J, de Marsily G (2001) Mississippi Valley-type lead-zinc deposits through geological time: implications from recent age-dating research. Mineral Deposita 36:711–740
Leach DL, Sangster DF (1993) Mississippi valley type lead-zinc deposits. In: Kirkham RV, Sinclair WD, Thorpe RI, Duke JM (eds) Mineral deposit modeling, Geol. Assoc. Can., Ontario, Spec Pap 40, pp. 289–314
Leach DL, Sangster DF, Kelley KD, Large RR, Garven Grant Allen CR, Gutzmer J, Walters S (2005) Sediment-hosted lead-zinc deposits: a global perspective: Society of Economic Geologists. Economic 1905–2005:561–607Geology One Hundredth Anniversary Volume
Leach DL, Taylor RD, Fey DL, Diehl SF, Saltus RW (2010) Deposit model for Mississippi Valley-type lead-zinc ore: chapter a of mineral deposit models for resource assessment. U.S. Geological Survey, Reston, Virginia, 51 p
Leach DL, Viets JG, Kozlowski Andrzej, Kibitlewski Stanislaw (1996) Geology, geochemistry, and genesis of the Silesia-Cracow zinc-lead district, southern Poland. In: Sangster DF (ed) Carbonate-hosted lead-zinc deposits Society of Economic Geologists, Special Publication 4, pp. 144–170
Lusk J, Calder BOE (2004) The composition of sphalerite and associated sulfides in reactions of the Cu-Fe-Zn-S, Fe- Zn-S and Cu-Fe-S systems at 1 bar and temperatures between 250 and 535°C. Chem Geol 203:319–345
Misra KC (1999) Understanding mineral deposits. Kluwer Academic Publishers, Boston, MA
Ohle EL (1996) Significant events in the geological understanding of the southeast Missouri lead district. In: Sangster DF (ed) Carbonate-hosted lead-zinc deposits. Society of Economic Geologists Special Publication 4, pp. 1–7
Pring A, Etschmann B (2002) HRTEM observations of structural and chemical modulations in cosalite and its relationship to the lillianite homologues. Mineral Mag 66:451–458
Reichert J (2007) A metallogenic model for carbonate-hosted non-sulfide zinc deposits based on observation of Mehdi Abad and Irankuh, central and southwestern Iran. PhD thesis. Martin Luther University, Halle Wittenberg, Germany (unpubl.)
Reynolds N, Large D (2010) Tethyan zinc–lead metallogeny in Europe, North Africa, and Asia. Econ Geol Spec Publ 15:339–365
Rhodes D, Lantos EA, Lantos JA, Webb RJ, Owens DC (1984) ) pine point orebodies and their relation-ship to the stratigraphy, structure, dolomitization, and karstification of the middle Devonian barrier complex. Econ Geol 79:991–1055
Robertson M, Hall M, Meyer E (2013) Red Crescent Resources Limited Hakkari Zinc Project Turkey. NI 43–101 Technical Report on the Hakkari Zinc Project, Turkey (Revised). The MSA Group (Pty) Ltd for Red Crescent Resources Limited, Specialist Consultants to the Mining Industry. MSA Project No. J 2720, 135p
Sangster DF (1995) Mississippi Valley-type lead-zinc. In: Eckstrand OR, Sinclair WD, Thorpe RI (eds) Geology of Canadian mineral deposit types. Geological Survey of Canada, Ottawa, pp. 253–261
Santoro L, Boni M, Herrington R, Clegg A (2013) The Hakkari nonsulfide Zn–Pb deposit in the context of other nonsulfide Zn–Pb deposits in the Tethyan Metallogenic Belt of Turkey. Ore Geol Rev 53:244–260
Sattarzadeh Y, Cosgrove JW Vita-Finzi C (2002) The geometry of structures in the Zagros cover rocks and its neotectonic implications. In: Clift PD et al (eds) The tectonic and climatic evolution of the Arabian Sea Region. Geological Society Special Publication 195, p 205–217
Sverjensky DA (1981) The origin of a Mississippi Valley-type deposit in the viburnum trend, Southeast Missouri. Econ Geol 76:1848–1872
Sverjensky DA (1986) Genesis of Mississippi Valley-type lead-zinc deposits. Annu Rev Earth Planet Sci 14:177–199
Szabo F, Kheradpir A (1978) Permian and Triassic stratigraphy southwest Iran. Jour Petr Geol 1:57–82
Szuwarzynsk M (1999) Ore bodies in the Silesian-Cracow Zn-Pb ore district, Poland, carbonate-hosted zinc-lead deposits in the Silesian-Cracow area. Poland, CLIV, pp. 9–24
Velasco F, Herrero JM, Yusta I, Alonso JA, Seeboid I, Leach D (2003) Geology and geochemistry of the Reocı’n zinc–lead deposit, Basque-Cantabrian Basin, northern Spain. Econ Geol 98:1371–1396
Ye L, Cook NJ, Ciobanu CL, Liu Y, Zhang Q, Liu T, Gao W, Yang Y, Danyushevskiy L (2011) Trace and minor elements in sphalerite from base metal deposits in South China: a LA-ICPMS study. Ore Geol Rev 39:188–217
Yigit O (2009) Mineral deposits of Turkey in relation to Tethyan metallogeny: implications for future mineral exploration. Econ Geol 104:19–51
Zhou J, Huang Z, Zhou M, Zhu X, Muchez P (2014) Zinc, sulfur and lead isotopic variations in carbonate-hosted Pb-Zn sulfide deposits, Southwest China. Ore Geol Rev 58:41–54
Zhou J, Huang Z, Zhou M, Li X, Jin Z (2013) Constraints of C-O-S-Pb isotope compositions and Rb-Sr isotopic age on the origin of the Tianqiao carbonate-hosted Pb-Zn deposit, SW China. Ore Geol Rev 53:77–92
Acknowledgments
This work is a part of a post-doctoral research that was conducted in the Geological Faculty, Warsaw University through a research scholarship by Erasmus Mundus-Salam Project 2. The European Commission is gratefully acknowledged for the financial support. My thanks go to Erasmus Mundus and staff of the Geological Faculty at the Warsaw University, in particular those who worked on XRD and SEM-EPMA investigations and EPMA (Cameca SX100) and SEM (JEOL JSM-6380LA) laboratories.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Awadh, S.M., Nejbert, K. Polymetallic sulfide ores hosted in Late Permian carbonate at the Alanish locality, northern Iraq: petrography and mineral chemistry. Arab J Geosci 9, 540 (2016). https://doi.org/10.1007/s12517-016-2571-y
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12517-016-2571-y