Micro-texture and mineralogy of Fe-Ti oxides from Qareaghaj mafic-ultramafic intrusion, NW Urmia

Abstract

: Detailed studies on micro-texture and microprobe analysis of Fe-Ti oxides from Qareaghaj mafic-ultramafic intrusion (QMUI) is the basis of this investigation. The QMUI is mainly composed of non-mineralized mafic and Fe-Ti-P-rich ultramafic rocks (FTP). The FTP with high proportion of ilmenite (~11-19 modal %) and magnetite (~2-13 modal %) show an unusual bulk composition. Fe-Ti oxides are divided into three distinct generations on the basis of their micro-texture: 1) small-sized rounded to ellipsoid-shape inclusion in olivine and clinopyroxene, 2) coarse interstitial grains and 3) late stage veinlets. The ilmenite grains (0.1-2mm) commonly contain fine hematite lenses arranged in [0001] planes. Primary Ti-magnetites contain ilmenite lamellae along the [111] planes and exhibit wide variety of exsolution textures (e.g., trellis- and sandwich-types). Ilmenite in FTP show Xilm range from 0.82-0.91 and has high MgO (0.82-2.38 wt %). Most Ti-magnetites (bulk composition) have low Xusp < /sub> (0.03-0.13) and therefore high Xmag (0.79-0.93). Two oxide geothermobarometer in the ILMAT program, resulted in re-equilibration temperature range of 450-700ْ C and ƒO2 (nearly -19±3) during subsolidus cooling for FTP rocks.

Keywords

References

[1] Haghipour A., Aghanabati A., “Geological quadrangle map of Iran No. A3. Serow sheet, Series 1:250000”, Geological Survey of Iran (GSI), (1973) Tehran.

[2] کاوشگران، مهندسین مشاور، "گزارش پتانسیل یابی مواد معدنی در منطقه شمالغرب شهرستان ارومیه"، تهران (1371).

[3] کاوشگران، مهندسین مشاور، "گزارش طرح اکتشاف نیمه تفضیلی تیتان و فسفات در منطقه قره آغاج"، تهران (1375).

[4] کاوشگران، مهندسین مشاور، "گزارش مطالعه فرآوری تیتان و فسفات منطقه قره آغاج ارومیه (در مقیاس آزمایشگاهی)" ، تهران (1376).

[5] کاوشگران، مهندسین مشاور، "گزارش طرح اکتشاف تفضیلی تیتان قره آغاج ارومیه (فاز یک)" ، تهران (1377).

[6] علیپور اصل، م.، " بررسی زمین شناسی اقتصادی و پترولوژی مجموعه آذرین مافیک و اولترامافیک ایلمنیت - آپاتیت‌دار شمال قره آغاج ارومیه"، پایان نامه کارشناسی ارشد، دانشگاه شهید بهشتی (1375) 269 صفحه.

[7] امامعلی‌پور ع.، مسعودی ج.، عبداللهی شریف ج.، " بررسی زمین‌شناسی اقتصادی و کانه‌آرایی مقدماتی کانسار ایلمنیت- آپاتیت قره آغاج ارومیه"، سومین همایش انجمن زمین‌شناسی ایران (1378)

[8] رحیم سوری ی.، "بررسی اکتشافی پتانسیل تیتانیم قره آغاج ارومیه"، پایان نامه کارشناسی ارشد، دانشگاه تربیت معلم تهران (1380) 154 صفحه.

[9] Owens B. E., Dymek R. F., “Fe-Ti-P-rich rocks and massif anorthosite: problems of interpretation illustrated from the Labrieville and St-Urbain plutons, Quebec”, Can Mineral 30 (1992) 163-190.

[10] Kolker A., “Mineralogy and geochemistry of Fe-Ti oxide and apatite (nelsonite) deposits and evaluation of the liquid immiscibility hypothesis”, Econ Geol 77 (1982) 1146-1158.

[11] Morse S. A., “The differentiation of the Skaergaard intrusion. Discussion of Hunter and Sparks”, (Contrib Min Petrol. 95:451-461), Contrib Min Petrol 104 (1990) 235

[12] Force E. R., “Geology of titanium mineral deposit”, Geological Society of America Special Paper 259 (1991) 112p

[13] Duchesne J. C., “Fe-Ti deposits in Rogaland anorthosites (South Norway)”, eochemical characteristics and problems of interpretation”, Mineral Deposita 34 (1999) 182-198

[14] Markl G., “REE constraints on fractionation processes of massive-type anorthosites on the Lofoten Islands, Norway”, Mineral Petrol 72 (2001) 325-351.

[15] Dymek H. F., Owens B. E., “Petrogenesis of apatite-rich rocks (nelsonites and oxide-apatite gabbronorites) associated with massif anorthosites”, Econ Geol 96 (2001) 797-815

[16] Buddington A. F., Lindsley D. H., “Iron-titanium oxide minerals and synthetic equivalents”, J. petrol 5 (1964) 310-357

[17] Haggerty S. E., “Oxide textures: A mini-atlas. In: Lindsley DH (ed) Oxide Minerals: Petrologic and Magnetic Significance”, Reviews in Mineralogy 25 (1991) 129-219

[18] Mirmohammadi M., Kananian A., Tarkian M., “The nature and origin of Fe-P-Ti-rich rocks in the Qareaghaj mafic-ultramafic intrusion, NW of Iran”, Mineral Petrol, in press

[19] Bishop F. C., “The distribution of Fe2+ and Mg between coexisting ilmenite and pyroxene with applications to geothermometery”, Am J Sci 280 (1980) 46-77

[20] Kretz R., “Metamorphic Crystallization”, John Wiley & Sons (1994) 507 pp

[21] Andersen D. J., Lindsley D. H., “New (and final!) models for the Ti-magnetite/ilmenite geothermometer and oxygen barometer”, EOS 66 (1985) 416.

[22] Lepage L. D., “ILMAT: An Excel worksheet for ilmenite-magnetite geothermometery and geobarometery”, Comp Geosci 29 (2003) 673-678

[23] Frost B. R., Lindsley D. H., “Equilibria among Fe-Ti oxides, pyroxenes, olivine and quartz: Part II. Application”, Am Mineral 77 (1992) 1004–1020.

[24] Toplis M. J., Dingwell D. B., Libourel G., “The effect of phosphorus on the iron redox ratio, viscosity and density of an emodalved ferro-basalt”, Contrib Mineral Petrol 117(1994) 293-304

[25] Zhou M. F., Robinson P. T., Lesher M., Keays R. R., Zhang C. J., Malpas J., “Geochemistry, petrogenesis and metallogenesis of the Panzhihua gabbroic layered intrusion and associated Fe-Ti-V oxide deposits, Sichuan province, SW China”, J. petrol 46 (2005) 2253-2280

[26] Kärkkäinen N. K., Appelqvist H., “Genesis of a low-grade apatite-ilmenite-magnetite deposit in the Kauhajärvi gabbro, Western Finland”, Mineral Deposita 34 (1999) 754-769.

[27] Mücke A., Younessi R., “Magnetite-apatite deposits (Kiruna-type) along the Sanandaj-Sirjan zone and in the Bafq area, Iran, associated with ultramafic and calcalkaline rocks and carbonatites”, Mineral Petrol 50 (1994) 219-244.

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History

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

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