Investigation genesis of massive dolomitic host rock with used Isotopic, petrology and REEs geochemical signatures at Ahmadabad deposit

Document Type : Original Article

Authors

1 Department of Basic Sciences, Farhangian University, Tehran, Iran

2 Department of Geology, Faculty of Earth Sciences, University of Shahid Beheshti, Tehran, Iran

Abstract

Introduction
Ahmadabad deposit is the northernmost old mine of Kuhbanan-Bahabad belt, located 10 km NE of Bahabad and is located in the stratigraphic sequence of calcareous-dolomitic Shotori formation. The predominant form of mineralization of Pb and Zn deposits in the region is of vein type, fissure, filling and substitution. Previous studies on the Ahmadabad deposit have considered the sedimentary genesis of the mineral to be sedimentary and the dolomitization to be due to the process of burial diagenesis in a lagoon environment. Due to the fact that the dolomites of the region are the main hosts of mineralization and a large amount of minerals are located in these rocks, the present study has focused on these rocks.
Materials and Methods
Dolomite-Carbonate units form the main volume of rocks in the area. Necessary information for investigating the genesis of dolomites was obtained from thin-polished cross-section, stable isotopic oxygen data and ICP-MS analysis, which was performed inside and outside Iran.
Results and Discussion
Microscopic studies show that dolomite crystals are formed in two stages and are visible with a gradual transition border and in some cases sharp border. The bright dolomites of the first stage darken in the next stage. Delayed dolomites are rhomboids with a sharp border and their outer part is covered by iron hydroxides. It is possible that the dolomites are oxidized due to stunted growth of Calcite cement within cavities bounded by dolomite, the presence of some calcite adjacent to dolomites, thick or thin zoning of the sharp boundary between calcite and dolomite, corrosion and dissolving at the junction, the presence of small amounts of Sulfides, oxides. Also, Cu-carbonates with lateral dolomite residues may indicate delayed formation of the oxidized margin of the dolomite. These features are compatible with the characteristics of hydrothermal dolomites in other parts of the world, such as hydrothermal dolomites southwest of the Cantabrian region of Spain. Isotopic data indicate the range of changes of δ18O-SMOW oxygen isotopic composition in the dolomitic rock of Ahmadabad deposit between 23.1‰ to 28.2‰. This value is close to the values reported in other hydrothermal dolomites of the world. The average values of δ18O-PDB in Shotori dolomites of Kuhbanan range are equal to -6.47‰. This value is also in the δ18O-PDB range of other hydrothermal dolomites. Comparison of Fe/Mg ratio in host rock and mineral also shows a 35-fold decrease in this ratio in the host rock. Studies have also shown the relative high level of deposit elements in the host unit. The available data indicate that Mg is used in the mineralization of hydrothermal fluids in the process of dolomitization of carbonate units. Hydrothermal fluids during mineralization have increased compared to poor Mg and its’ Fe content. Comparison of distribution patterns between minerals and rocks in the region shows an undeniable similarity between these minerals and carbonate rocks. The relationship  (  also reveals the increase and enrichment of rare earth elements in light to heavy types. The average ratio in carbonate units is 14.24. This ratio for minerals averages 14.63 and is very close to the average of total carbonates.
Conclusion
The findings of this study showed that the dolomites of the Shotori Formation in the study area were formed under the influence of hydrothermal solutions of metal-rich basins, which were also responsible for mineralization. Evidence from microscopic studies and stable isotopic data of δ18O-SMOW is consistent with the characteristics of hydrothermal dolomites in other parts of the world. The similarity of the normalized patterns of REEs in the host rock and mineral as well as the consistency of the variation in the ratio of Fe and Mg elements between the mineral and the host rock also confirm the result obtained. The similarity of the of the REEs of the host rock and mineral and the concordance of the ratio of Fe and Mg elements between the mineral and the host rock also confirm the result obtained.

Keywords

References

-Aghanabati, A., 2004. Geology of Iran: Tehran, Iran, Geological Survey of Iran, 600 p.
-Alimohammadi, M., 2015. Characteristics of Alteration, Mineralization, Source and Transformation of Mineral Fluid and Evaluation of Controlling Factors with Copper Rory in Porphyry Copper Deposits in Aloo and Sarmeshk, South of Kerman, PhD Thesis, Shahid Beheshti University, 157 p.
-Amani Lari, S., 2016. Mimeralogy and Genesis of Zn and Pb(Mo) Ahmadabad Deposit (NE of Bafq). PhD Thesis in Economic geology. Islamic Azad University, North Tehran Branch, 286 p.
-Amani Lari, S., Rassa, I. and Amiri, A., 2017. Stable C-O Isotopes geochemistry of Ahmadabad zn-Pb-Mo non-Sulfide deposit (NW Bahabad). Scientific Quarterly Journal, Geosciences: v. 26(103), p. 72-83.
-Amiri, A., 2007. The Geological and geochemical characteristics and genesis of the carbonate-hosted zinc-lead deposits in the Ravar-Bafgh area. Unpublished Ph.D dissertation, Islaic Azad University, Science and Research Branch, Tehran, 315 p.
-Amiri, A., Rassa, I., Khakzad, A. and Adabi, M.H., 2009.Thermometry and formation model of carbonate- hosted Zn-Pb sulfide deposits in the Ravar- Bafgh area based on sulfur stable isotopes. Scientific Quarterly Journal, Geosciences, v.18, p. 3-10.
-Boni, M., Parente, G., Bechstadt, T., De Vivo, B. and Iannace, A., 2000. Hydrothermal dolomites in Sardinia (Italy): evidence for a widespread late-Variscan fluid flow event, Sedimentary Geology, v. 131, p. 181-200.
-Boni, M., Gilg, H.A., Aversa, G., and Balassone, G., 2003. The “Calamine” of SW Sardinia (Italy): geology, mineralogy and stable isotope geochemistry of Economic Geology, v. 98, p. 731-748.
-Gasparrini, M., Bechstadt, T. and Boni, M., 2006. Massive hydrothermal dolomites in the southwestern Cantabrian Zone(Spain) and their relation to the Late Variscan evolution. Marine and Petroleum Geology, v. 23, p. 543-568.
-Gilg, H.A., Boni, M., Hochleitner, R. and Struck, U., 2008. Stable isotope geochemistry of carbonate minerals in supergene oxidation zones of Zn-Pb deposits: Ore Geology Revews, v. 33, p. 117-133.
-Hitzman, M.W., Reynolds, N.A., Sangster, D.F., Allen, C.R. and Carman, C.E., 2003. Classification, genesis, and exploration guides for nonsulfide Zinc deposits: Economic Geology, v. 98, p. 685-714.
-Javanshir, A., 2007.Mineralogy, geochemistry, faciesanalysis and genesis of Zn-Pb(Mo) mineralization in Shotori Formation dolomites of the Ahmadabad deposit(NE-Bafq). M.Sc, thesis, Tarbit Modares University, Tehran, Iran (unpubl).
-Karimzadeh, F. and Adaabi, M.H., 2008. Description Of Different Kinds Of Dolomites In Shotori Formation (Kouhbanan Area) Based On Petrographic And Geochemical Studies With A Reference To The Role Of Shales Inthe Sorkh Shale Formation As A Major Source Of Mg. GEOSCIENCES, v. 18(69), p. 110-129.
-Land, L.S., 1985. The origin of massive dolomite. Journal of Geological Education, v. 33, p. 112-125.
-Mondillo, N., 2014.  Supergen Nonsulfide Zinc-Lead Deposits: The Examples og Jaballi (Yaman) and Yanque (Peru), DOCTORAL THESIS in ECONOMIC GEOLOGY, University Digital Studi di Napoel “FEDRICII”, School in Earth Science, 185 p.
-Rajabi, A., Rastad, E. and Canet, C., 2013. Metallogeny of Permian-Trassic carbonate-hosted Zn-Pb and F deposits of Iran: Areview for future mineral exploration, Australian Geoscience Journal, v. 60, p. 197-216.
-Sun, S.S. and McDonough, W.F., 1989. Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes. In: Saunders AD, Norry MJ (eds) Magmatism in ocean basins: GeolSoclond Spec Pub, v. 42, p. 313-345.
 
English References:
-Boni, M., Parente, G., Bechstadt, T., De Vivo, B. and Iannace, A., 2000. Hydrothermal dolomites in Sardinia (Italy): evidence for a widespread late-Variscan fluid flow event, Sedimentary Geology, v. 131, p.181-200.
-Boni, M., Gilg, H.A., Aversa, G. and Balassone, G., 2003. The Calamine of SW Sardinia (Italy): geology, mineralogy and stable isotope geochemistry of Economic Geology, v. 98, p. 731-748.
-Gasparrini, M., Bechstadt, T. and Boni, M., 2006. Massive hydrothermal dolomites in the southwestern Cantabrian Zone(Spain) and their relation to the Late Variscan evolution. Marine and Petroleum Geology, v. 23, p. 543-568.
-Gilg, H.A., Boni, M., Hochleitner, R. and Struck, U., 2008. Stable isotope geochemistry of carbonate minerals in supergene oxidation zones of Zn-Pb deposits: Ore Geology Revews, v. 33, p. 117-133.
-Hitzman, M.W., Reynolds, N.A., Sangster, D.F., Allen, C.R. and Carman, C.E., 2003. Classification, genesis, and exploration guides for nonsulfide Zinc deposits: Economic Geology, v. 98, p. 685-714.
-Land, L.S., 1985. The origin of massive dolomite. Journal of Geological Education, v. 33, p. 112-125.
-Mondillo, N., 2014.  Supergen Nonsulfide Zinc-Lead Deposits: The Examples og Jaballi (Yaman) and Yanque (Peru), DOCTORAL THESIS in ECONOMIC GEOLOGY, University Digital Studi di Napoel FEDRICII, School in Earth Science, 185 p.
-Rajabi, A., Rastad, E. and Canet, C., 2013. Metallogeny of Permian-Trassic carbonate-hosted Zn-Pb and F deposits of Iran: Areview for future mineral exploration, Australian Geoscience Journal, v. 60, p. 197-216.
-Sun, S.S. and McDonough, W.F., 1989. Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes. In: Saunders AD, Norry MJ (eds) Magmatism in ocean basins: GeolSoclond Spec Pub, v. 42, p. 313-345.
 

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