Mineralogy and genesis of serpentine group minerals in serpentinites of the Baft ophiolite mélange in Kerman province

Abstract

Three types of serpentine polymorphs (lizardite, chrysotile and antigorite) are found in serpentinites from the Baft ophiolite mélange which are different in the textural features and chemical compositions. Lizardite is seen as layered structures that set in the matrix of peridotites, while antigorite is formed in veins or sheared zones as blade crystals and chrysotile develops as shiny and golden fibers in small cracks. The studied peridotites, based on degree of serpentinization, can be divided into three subdivisions including relatively serpentinized peridotites (up to 50 vol. % serpentinization), mainly serpentinized peridotites (50-90 vol. % serpentinization) and completely serpentinized peridotites (90-100 vol. % serpentinization). We suggested three models for serpentinization of olivine in this area. First model contains serpentinization of olivine grain boundaries with unaltered centers. The process has developed in relatively serpentinized peridotites. Second model includes redeveloping serpentinization of inherited olivine grains from the first model and third model contains complete serpentinization of olivine grains. Second and third models have been developed in mainly and completely serpentinized peridotites. It seems that involved lizardite and chrysotile are the result of static alteration in an ocean floor like environment, while interpenetrative-blade antigorites have been produced by dynamic metamorphism. Production of antigorite can be related to subduction of Nain-Baft oceanic crust or it can be related to obduction of serpentinized pridotites in other times, it is possible that lizardite and chrysotile have formed before closure of Nain-Baft Small Ocean.

Keywords

References

[1] Boudier F., Baronnet A., Mainprice D., “Serpentine Mineral Replacements of Natural Olivine and their Seismic Implications: Oceanic Lizardite versus Subduction-Related Antigorite”, Journal of Petrology (2009) Doi:10.1093/petrology/egp049.

[2] Facer J., Downes H., Beard, A., “In situ Serpentinization and Hydrous Fluid Metasomatism in Spinel Dunite Xenoliths from the Bearpaw Mountains, Montana, USA”, Journal of Petrology, 50 (2009) 1443-1475.

[3] Davoudzadeh M., “Geology and Petrography of the Area North of Nain, Central Iran”, Geological Survey of Iran Report, 14 (1972) 89.

[4] Berberian M., King, G.C.P., “towards a paleogeography and tectonic evolution of Iran”, Canadian J. of Earth Sciences, 18 (1981) 210–265.

[5] Desmons J., Beccaluva L., “Mid-ocean ridge and island arc affinities in ophiolites from Iran Paleographic implications”, Chemical Geology, 39 (1983) 39– 63.

[6] Shahabpour J., “Tectonic evolution of the orogenic belt in the region located between Kerman and Neyriz”, Journal of Asian Earth Science, 24 (2005) 405-417.

[7] Prichard H. M., “A Petrographic Study of the Process of Serpentinization in Ophiolites and the Ocean Crust”, Contributions to Mineralogy and Petrology, 68 (1979) 231-241.

[8] Wicks F. J., Whittaker E.J.W., Zussman j., “An idealized model for serpentine textures after olivine”, Canadian Mineralogist, 15 (1977) 446-458.

[9] Wang X., Zeng Z., Chen J., “Serpentinization of peridotites from the southern Mariana forearc”, Progress in Natural Science, 19 (2009) 1287–1295.

[10] Hopkinson L., Beard J. S., Boulter C. A., “The hydrothermal plumbing of a serpentinite-hosted detachment: evidence from the West Iberia non-volcanic rifted continental margin, Marine” Geology, 204 (2004) 1–15.

[11] Francis G.H., “The serpentinite mass in Glen Urquhart, Inverness-shire, Scotland”, American Journal of Science, 254 (1956) 201-226.

[12] Wicks F.J., Whittaker E. J. W., “Serpentine textures and serpentinasation”, Canadian Mineralogist, 15 (1977) 459-488.

[13] Moore D.E., Lockner D.A., Ma Shengli, Summers R., Byerlee J.D. “Strength of chrysotile-serpentinite gouge under hydrothermal conditions. Can it explain a weak San Andreas fault?”, Geology, 24 (1996) 1041–1044.

[14] Passchier C.W., Truw R.A.J., “Micro-tectonics”, Berlin, Springer- Verlag (1998) 289 p.

[15] Güartekin G., Albayrak, M., “Thermal reaction of antigorite: A XRD, DTA-TG work”, Mineral Res. Exp., Bull, 133(2006) 41-49.

[16] Ashwal, L. D., Cairncross B., “Mineralogy and origin of stichtite in chromite–bearing serpentinites”, Contributions to Mineralogy and Petrology, 127 (1997) 75–86.

[17] Hajialioghli R., Moazzen M., Droop G.T.R., Oberhänsli R., Bousquet R., Jahangiri A., Ziemann M., “Serpentine polymorphs and P-T evolution of metaperidotites and serpentinites in the Takab area, NW Iran”, Mineralogical Magazine, 71 (2007) 203-222.

[18] Hey M.H., “A new review of the chlorites”, Mineralogical Magazine, 30 (1954) 277-292.

[19] Pelletier L., Vilsi V., Kalti A. and Gmeling K., “Li, B and Be Contents of Harzburgites from them Dramala Complex (Pindos Ophiolite, Greece): Evidence for a MOR-type Mantle in a Supra-subduction Zone Environment”, Journal of Petrology, 49 (2008) 2043-2080.

[20] Whittaker E. J. W., Wicks F. S., “Chemical differences among serpentine polymorphs: a discussion”, American mineralogist, 55 (1970) 1025-47.

[21] O`Hanley D. S., “Serpentinites- Records of Tectonic and Petrological History”, Oxford University Press, (1996) 277.

[22] Ghasemi C.J. Talbot, “A new tectonic scenario for the Sanandaj–Sirjan Zone (Iran)”, J. of Asian Earth Sciences, 26 (2006) 683–693.

[23] González-Mancera G., Ortega-Gutiérrez F., Proenza J. A., Atudorei V., “Petrology and geochemistry of Tehuitzingo serpentinites (Acatlán Complex, SW Mexico)”, Boletin de la Sociedad Geologica Mexicana, 61 (2009) 419-435.

[24] O’Hanley D.S., Offer R., “Characterisation of multiple serpentinizations, Woodsreef, New South Wales”, Canadian Mineralogist, 30 (1992) 1113-1126.

[25] Wicks F.J., Plant A.G., “Electron-microprobe and x-ray microbeam studies of serpentinite textures”, Canadian Mineralogist, 17 (1979) 785-830.3

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History

  • Receive Date: 02 July 2025
  • Revise Date: 04 February 2026
  • Accept Date: 02 July 2025

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