Mineralogy, chemistry and genesis of bentonite of the Eocene sediments at Aftar region, western Semnan

Abstract

The bentonites of Aftar region, with average of 15 meters thickness and about 10 km long, are volcanoclastic sequence of Semnan Formation that formed in a shallow sea water environment. Based on the field, XRD data, microscopic and scanning electron microscopic (SEM) studies, as well as chemistry, the bentonite beds contain zeolites (clinoptilolite and mordenite), gypsum, calcite, celestine, opal, quartz, crystobalite and aragonite associated with clay minerals. XRD data of air-dried, glycolated and heated of clay fractions show the majority of the clay minerals are of swelling and of dioctahedral, smectite types. FTIR spectra, in agreement with chemical analyses data, reveal that the smectites are of Wyoming type (SWy-2) montmorillonite. The structural formula unit of representative clay of Aftar region, based on 11 oxygens, is:

(Ca0.057Na0.270K0.030)(Al1.515Mg0.313Fe0.109Ti0.010)(Si4.015O10)(OH)2.

Based on the composition of tuff and bentonites, the bentonites appear to be derived from alteration of acidic (dacitic to rhyolitic) tuffs of Eocene age in a relatively basic environment. Relatively stable smectites and zeolites are formed by dissolutim of less stable glass of vitric ash that was present in tuff during variation in basic environmental conditions.

Keywords

References

[1] حجازی مجتبی، قربانی منصور، "بنتونیت-زئولیت"، سازمان زمین شناسی، (1373) صفحه 108.

[2] افتخارنژاد جمشید، "گزارش عملیات اکتشافی خاک صنعتی (زئولیت-بنتونیت) شمال غرب هفدر، استان سمنان"، (1374) صفحه 132.

[3] Velde B., "Introduction to clay minerals", Chapman and Hall (1992) p. 198.

[4] نبوی محمد حسن، زمین شناسی ناحیه سمنان، چهارگوش شماره 6661 سری 000/1:100 سازمان زمین شناسی کشور (1366).

[5] Hüber H., Mohafez S., "Geological reconnaissance in North Semnan area", GR. 334, NIOC. (1972) p. 34.

[6] Gibbs R.J., "Error due to segregation in quantitative clay mineral X-ray diffraction mounting techniques", American Mineralogist 50 (1965) 741.

[7] Gibbs R.J., "Clay mineral mounting techniques for X-ray diffraction analysis, A discussion", Journal of Sedimentary Petrology, 38 (1968) 242.

[8] Choo O.Ch., Chang T.W., "Characteristics of clay minerals in gouges of Dongrae fault, south eastern Korea, and implications for fault activity", Clays and clay Minerals 48 (2000) 1204.

[9] Colak M., Helvaci C., Maggetti M., "Saponite from Emet colemanite mines, Kütahya, Turkey", Clays and Clay Minerals 48, (2000) 409.

[10] Tomita K., Yamane H., Kawano M., "Synthesis of smectite from volcanic glass at low temperature", Clays and Clay Minerals 41, (1993) 655.

[11] Giresse P., Wiewióra A., "Origin and digenesis of blue-green clays and volcanic glass in Pleistocene of Côte d’ Ivoire-Ghana Marginal Ridge (ODP leg 159, Site 959)", Sedimentary Geology 127, (1999) 247.

[12] Madejová J., Komadel P., "Baseline studies of the clay minerals society source clays: Infrared method", Clays and Clay Minerals 49, (2001) 410.

[13] Wilson M.J., "Clay mineralogy: spectroscopy and chemical determination methods", Chapman and Hall (1994) p. 367.

[14] Cuadros J., Altaner S.P., "Characterization of mixed-layer illite-smectite from bentonites using microscopic, chemical, and X-ray methods: Constraints on smectite-to-illite transformation mechanism", American Mineralogist 83, (1998) 762.

[15] Mermut A.R., Cano A.F., "Baseline studies of the clay minerals society source clays: Chemical analyses of major elements", Clays and Clay Minerals, 49 (2001) 381.

[16] Son B.K., Yoshimur T., Fukasawa, H., "Diagenesis of dioctahedral and trioctahedral smectites from alternating beds in Miocene to Pleistocene rocks of Niigata Basin, Japan", Clays and Clay Minerals 42 (2001) 333.

[17] Spears D.A., Kanaris-Sotiriou Riley N., Krause P., "Namurian bentonites in Pennine Basin, UK-origin and magmatic affinities", Sedimentology 46 (1999) 385.

[18] Moore D.M., Reynolds Jr.R.C., "X-ray diffraction and identification and analysis of clay minerals", Oxford University Press (1989) p. 332.

[19] Broxton D.E., Bish D.L., Warren R.G., "Distribution and chemistry of digenetic minerals at Yucca mountain, New County, Nevada", Clays and Clay Minerals 35, (1987) 89.

[20] Masuda H., O’neil J.R., Jiang W.T., Peacor DR., "Relation between interlayer composition of authigenic smectite, mineral assemblages, I/S reaction rate and fluid composition in silicic ash of ankai trough", Clays and Clay Minerals 44, (1996) 443.

[21] Hay R.L., Guldman S.G., "Diagenetic alteration of silicic ash in searles lake, California", Clays and Clay Minerals 35 (1987) 440.

[22] بازرگانی گیلانی کمال الدین، ربانی محمد صادق، "نهشت سلستین چینه‌کران منطقه افتر، غرب سمنان"، فصلنامه علمی پژوهشی علوم زمین، در دست چاپ.

[23] Christidis G.E., "Formation and growth of smectites in bentonites: A case study from Kimolos island, Aegean, Greece", Clays and Clay Minerals 49 (2001) 204.

[24] Moll Jr.W.F., "Baseline studies of the clay minerals society source clays: Geological origin", Clays and Clay Minerals 49 (2001) 374.

[25] Surdam R.C., Parker R.D., "Authigenic aluminosilicate minerals in the tuffaceous rocks of the Green River Formation", Wyoming. Geol. Soc. of Am. Bull. 83 (1972) 689.

[26] Manning D.A.C., Hall P.L., Hughes C.R., "Geochemistry of clay-pore fluid interaction", Chapman and Hall (1993) p. 427.
Iranian Journal of Crystallography and Mineralogy
Volume 12, Issue 2 - Serial Number 22
October 2004
Pages 169-188

Files

History

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

Share

How to cite

Statistics