A Geochemical and Geostatistical Approach to the Origin of the Sarfaryab Bauxite Deposits, Kohgiloyeh-va-Boyrahmad Province, SW Iran

Ehya, F.; Lotfi, M.

doi:10.22071/gsj.2010.57325

Document Type : Original Research Paper

Authors

F. Ehya ¹
M. Lotfi ²

¹ Geology Department, Islamic Azad University, Behbahan Branch, Behbahan, Iran

² Geology Department, Islamic Azad University, North Tehran Branch, Tehran, Iran

https://doi.org/10.22071/gsj.2010.57325

Abstract

The Sarfaryab bauxite deposits occur in karstic depressions at the top of the limestones of the Cenomanian to Lower Turonian Sarvak Formation, which are overlain by the limestones of the Santonian Ilam Formation. In order to determine the possible source rocks of the Sarfaryab bauxite deposits, a few samples were collected from Sarvak Formation, terra rossa and bauxite ore and geochemically and geostatistically analyzed. Plots of chemical data and correlation coefficients show that Al, Ti, Zr, Nb, Cr and V were immobile during the bauxitization process. In the scatter diagrams of Zr and TiO₂ versus Al₂O₃, regression lines pass through the origin and terra rossa falls between the Sarvak Formation and bauxite. Based on this research, it can be stated that the source rock of the Sarfaryab bauxite deposits is the Sarvak Formation and terra rossa is an intermediate product during limestone-bauxite transformation. Post-Turonian uplift had exposed recently deposited limestones of the Sarvak Formation to karst weathering, and a layer of argillaceous debris accumulated on its surface and was partly converted to bauxite. Subsidence followed, and the bauxite was preserved by the deposition of limestones of the Ilam Formation. Uplift in Pliocene time, with ensuing erosion, exposed the bauxite deposits to their present situation.

Keywords

20.1001.1.10237429.1388.19.74.13.8

References

References

Alavi, M., 2004- Regional stratigraphy of the Zagros fold-thrust belt of Iran and its proforland evolution, American Journal of Science, 304: 1-20.

Bardossy, G., 1982- Karst bauxites; bauxite deposits of carbonate rocks, Amsterdam, Elsevier.

Bardossy, G., 1984- European bauxite deposits. In: Jacob Leonard Jr (ed.), Proceedings of 1984 Bauxite Symposium, Los Angeles, California, Society of Mining Engineers, New York, 411-435.

Brimhall, G. H., Lewis, C. J., Ague, J. J., Dietrich, W. E., Hampel J., & Rix, P., 1988- Metal enrichment in bauxites by deposition of chemically mature aeolian dust, Nature, 333: 819-824.

Bushinsky, G. I. & Zakrutkin, V. E., 1978- Geochemistry of bauxites of the South Timan, Nauka, Moscow, 122 pp. (in Russian).

D’Argenio, B. & Mindszenty A., 1995- Bauxites and related paleokarst: Tectonic and climatic event markers at regional unconformities, Eclogae Geologicae Helvetiae, 88: 453-499.

Gow, N. N., & Lozej, G. P., 1993- Bauxite, Geosci. Can., 20: 9-16.

Hill, I. G., Worden., R. H., & Meighan, I. G., 2000- Geochemical evolution of a paleolaterite: The Interbauxitic Formation, Northern Ireland, Chem. Geol., 166: 65-84.

Iranian Oil Operating Companies, 1973- Dehdasht geological compilation map, 1 : 100000.

Jennings, J. N., 1985- Karst, The MIT Press, Massachusetts.

Karadag, M. M., Arik, F. & Ozturk, A., 2006- A geochemical and geostatistical approach to the origin of the Catmakaya (Seydisehir - Türkiye) bauxite deposit, Yerbilimleri, 27 (2): 63-85, (in Turkish).

Khadkikar, S. A. & Basavaiah, N., 2004- Morphology, mineralogy and magnetic susceptibility of epikarst-terra rossa developed in late Quaternary aeolianite deposits of southeastern Saurashtra, India, Geomorphology, 58: 339-355.

Lelong, F., Tardy, Y., Grandin, G., Trescases, J. J. & Boulange, B., 1976- Pedogenesis, chemical weathering and processes of formation of some supergene ore deposits, Reprinted from: Handbook of Stratabound and Stratiform Ore Deposits. edited by K.H. Wolf, Elsevier Scientific Publishing Company, Amsterdam, Printed in The Netherlands.

Liaghat, S., Hosseini, M. & Zarasvandi, A., 2003- Determination of the origin and mass change geochemistry during bauxitization process at the Hangam deposit, SW Iran, Geochemical Journal, 37: 627-637.

Lyew-Ayee, P. A., 1986- A case for the volcanic origin of Jamaican bauxites, Proc. Bauxite Symposium VI,1986,J. Geol. Soc. Jamaica,9-39.

MacLean, W. H., 1990- Mass change calculations in altered rock series, Min. Dep., 25: 44-49.

MacLean, W. H. & Barrett, T. J., 1993- Lithogeochemical techniques using immobile elements, J. Explor. Geochem., 48: 109-133.

MacLean, W. H. & Kranidiotis, P., 1987- Immobile elements as monitors of mass transfer in hydrothermal alteration: Phelps Dodge massive sulfide deposit, Matagami, Quebec, Econ. Geol., 82: 951-962.

MacLean, W. H., Bonavia, F. F. & Sanna, G., 1997- Argillite debris converted to bauxite during karst weathering: evidence from immobile element geochemistry at the Olmedo Deposit, Sardinia, Min. Dep., 32: 607-616.

Miko, S., Durn, G. & Prohic, E., 1999- Evolution of terra rossa geochemical baselines from Croation karst region, J. Geochem. Explor., 66: 173-182.

Mordberg, L. E., 1993a- Associations of trace elements in bauxites and evolution of conditions of bauxite formation. In: S. Ishihara, T. Urabe and H. Ohmoto (Eds.), Proceedings of the 29th International Geological Congress, 1992, Resour. Geol. Spec. Iss., 15: 421-433.

Mordberg, L. E., 1996- Geochemistry of trace elements in Paleozoic bauxite profiles in Northern Russia, J. Geochem. Explor., 57: 187-199.

Mylorie, J. E. & Carew, J. L., 1995- Karst development on carbonate islands. In: D. Budd, P.M. Harris and A. Saller. (eds.), Unconformities and Porosity in Carbonate Strata. AAPG Memoir, Tulsa, 63: 55-76.

Ozturk, H., Hein, J. R. & Hanilci, N., 2002- Genesis of the Dogankuzu and Mortas Bauxite Deposits, Taurides, Turkey: Separation of Al, Fe, and Mn and Implications for Passive Margin Metallogeny, Econ. Geol., 97: 1063-1077.

Paktunc, A. D., 1998- MODAN: an interactive computer program for estimating mineral quantities based on bulk composition, Computers & Geosciences, 24 (5): 425–431.

Paktunc, A. D., 2001- MODAN: a computer program for estimating mineral quantities based on bulk composition: windows version, Computers & Geosciences, 27: 883-886.

Pye, K., 1988- Bauxites gathering dust, Nature, 333: 300-301.

Sastri, G. G. K. & Sastri, C. S., 1982- Chemical characteristics and evolution of the laterite profile in Hazaridadar Bauxite Plateau, Madhya Pradesh, India, Econ. Geol., 77: 154-161.

Stocklin, J. & Setudehnia, A., 1977- Stratigraphic Lexicon of Iran, Ministry of Information and Tourism Press, 376 pp.

Taylor, S. R. & McLennan, S. M., 1985- The Continental Crust: Its Composition and Evolution. Oxford, Blackwell Scientific Publishing, 312 p.

Temur, S., 2000- Ore Deposits, Nobel Publ., 208 pp.

Temur, S., 2006- A geochemical approach to parent rocks of the Masatdagi diasporic bauxite, Alanya, Antalya, Southern Turkey, Geochemistry International, 44: 941-952.

Temur, S., Orhan, S. H. & Kurt, H., 2005- Mass and volume change calculations of the Masatdagi (Alanya–Antalya) bauxites from Southern Turkey, Geochem. Intern.,43: 202-210.

Valeton, I., Biermann, M., Reche, R. & Rosenberg, F., 1987- Genesis of nickel laterites and bauxites in Greece during the Jurassic and Cretaceous, and their relation to ultrabasic parent rocks, Ore Geol. Rev., 2: 359-404.

Scientific Quarterly Journal of Geosciences

A Geochemical and Geostatistical Approach to the Origin of the Sarfaryab Bauxite Deposits, Kohgiloyeh-va-Boyrahmad Province, SW Iran

References

References

Volume 19, Issue 74 - Serial Number 74
February 2010
Pages 91-98

A Geochemical and Geostatistical Approach to the Origin of the Sarfaryab Bauxite Deposits, Kohgiloyeh-va-Boyrahmad Province, SW Iran

References

References

Volume 19, Issue 74 - Serial Number 74February 2010Pages 91-98

Volume 19, Issue 74 - Serial Number 74
February 2010
Pages 91-98