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Pruseth, Kamal L.
- Magnetic Spherules with Metallic Shine in the Recent Alluvium of Rajasthan
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Authors
Affiliations
1 Department of Earth Sciences, Pondicherry University, Pondicherry - 605 014, IN
2 Dept of Geology, M L Sukhadia University, Udaipur-313001, IN
1 Department of Earth Sciences, Pondicherry University, Pondicherry - 605 014, IN
2 Dept of Geology, M L Sukhadia University, Udaipur-313001, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 68, No 5 (2006), Pagination: 912-913Abstract
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- First Report of Eudialyte Occurrence from the Sushina Hill Region, Purulia District, West Bengal
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Authors
Affiliations
1 Department of Earth Sciences, IIT Roorkee, Roorkee - 247 667, IN
2 Institute Instrumentation Centre, IIT Roorkee, Roorkee - 247 667, IN
1 Department of Earth Sciences, IIT Roorkee, Roorkee - 247 667, IN
2 Institute Instrumentation Centre, IIT Roorkee, Roorkee - 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 77, No 1 (2011), Pagination: 12-16Abstract
Eudialyte is a group of hydrated silicate minerals essentially consisting of Na and Zr with a very complex crystal structure, and generally associated with alkaline rocks. The complexity of the eudialyte structure can be understood from the fact that Na alone exist in five distinct sites and extensive solid solubility can occur in almost all cation sites, sometimes one element occupying multiple sites to the extent of exclusion of other elements. Structurally, eudialyte can be represented as Na15[M1]6[M2]3Zr3[M3](Si25O73)(O,OH,H2O)3X2 (Johnsen and Grice, 1999), where M1 and M2 sites are occupied by Ca, Mn and Fe, M3 by Nb and X by OH, Cl and F. In addition, cations like Al, Hf, W, Ta, Sr, Ba and various REEs get incorporated into the eudialyte structure by substitution, and additional site vacancies even may develop in order to maintain electrical neutrality. Eudialyte, approximately of the composition Na9Ca8Mn3Nb(Zr,Ce)3Si25O73(OH)2, has hydrothermally replaced albite in the nepheline syenite gneiss exposed south of the Sushina hill of Purulia district, West Bengal. The eudialyte contains ≈2.25 atom% Zr and 0.75 atom% Nb. In addition to eudialyte in nepheline syenite, an unknown Na-Zr silicate (NZS) has also replaced the albite crystals. The NZS contains ≈ 7 atom% Zr with a possible empirical formula of Na12Zr11Si36O95(OH)10. Surface exposures of these rocks are limited at Sushina hill, yet a detailed and systematic investigation on this enigmatic rock is warranted for they may turn out to be a resource for Zr.Keywords
Eudialyte, Na-Zr Silicate (NZS), Agpaitic Nepheline Syenite, Sushina Hill.
- Compositions and Petrogenetic Significance of the Eudialyte Group Minerals from Sushina, Purulia, West Bengal
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Authors
Affiliations
1 Department of Geology, Durgapur Government College, Durgapur - 713 214, IN
2 Department of Geology and Geophysics, IIT Kharagpur, Kharagpur - 721 302, IN
3 Department of Earth Sciences, IIT Roorkee, Roorkee - 247 667, IN
1 Department of Geology, Durgapur Government College, Durgapur - 713 214, IN
2 Department of Geology and Geophysics, IIT Kharagpur, Kharagpur - 721 302, IN
3 Department of Earth Sciences, IIT Roorkee, Roorkee - 247 667, IN
Source
Journal of Geological Society of India (Online archive from Vol 1 to Vol 78), Vol 79, No 5 (2012), Pagination: 449-459Abstract
The eudialyte-group of minerals (EGM) is one of the most important index minerals of the peralkaline (agpaitic) nepheline syenites. They crystallize in varied physico-chemical conditions ranging from the early-magmatic (orthomagmatic) to late-magmatic and even in the post-magmatic (hydrothermal) stage. In India, the only agpaitic nepheline syenite gneisses of the Sushina Hill region contain both late-magmatic as well as hydrothermal eudialytes. Compositionally these are Mn-Nb-Ca rich eudialytes and are comparable to the other EGM occurrences such as Ilímaussaq (Greenland), Tamazeght (Morocco), Mont-Saint Hilaire (Canada) and Pilansberg (South Africa). High Mn content (>6.5 wt.%) for both varieties of the Sushina EGM indicates that they are highly evolved in nature. In terms of the calculated site occupancy, particularly the [M(3)] and [M(2)], the Sushina eudialytes mimic some Pilansberg eudialytes. In addition to the eudialyte, the host nepheline syenite gneiss also contains an unknown Na-Zr-silicate (NZS) which is often found to be replacing both types of eudialytes. Compositionally these NZS can be tentatively represented as Na2Zr2S6O17. These NZS are characterized by much higher Zr, but lower Mn and Nb concentrations compared to the associated eudialytes. Two distinct varieties of eudialyte and NZS indicate subtle changes in the alkalinity during their formations. The formation of the late-magmatic as well as hydrothermal eudialyte essentially took place at somewhat elevated pH conditions. The replacement or alteration of eudialytes by NZS indicates a decreasing pH condition. In terms of the chemical composition the late-magmatic eudialytes can be represented as a solid-solution series between the kentbrooksite-taseqite-aqualite while the hydrothermal eudialyte represents solid-solution between kentbrooksitetaseqite-Ce-zirsilite.Keywords
Eudialyte-Group of Minerals (EGM), Na-Zr Silicates (NZS), Agpaitic Systems, Late-Magmatic, Sushina Hill.References
- BIRKETT, T.C., MILLER, R.R., ROBERTS, A.C. and MARIANO, A.N. (1992) Zirconium-bearing minerals of the Strange Lake intrusive complex, Quebec-Labrador. Can. Min., v.30, pp.191-205.
- CHAKRABARTY, A. (2009) Petrogenesis of Carbonatite and Associated Alkaline Rocks, Purulia, W.B., India. Unpublished Ph.D. Thesis, Department of Earth Sciences, IIT Roorkee, Roorkee.
- CHAKRABARTY, A., PRUSETH, K.L. and SEN, A.K. (2011) First Report of Eudialyte Occurrence from the Sushina Hill Region, Purulia District, West Bengal. Jour. Geol. Soc. India, v.77, pp.12-16.
- COULSON, I.A. (1997) Post-magmatic alteration in eudialyte from the North Qoˆ roq centre, South Greenland. Min. Mag., v.61, pp.99-109.
- COULSON, I.A. and CHAMBERS, A.D. (1996) Patterns of zonation in rare-earth-bearing minerals in nepheline syenites of the North Qôroq center, South Greenland. Can. Min., v.34, pp.1163-1178.
- GERASIMOVSKIY, V.I., VOLKOV, V.P., KOGARKO, L.N. and POLYAKOV, A.I. (1974) Kola peninsula. In: H. Sørensen (Ed.), The alkaline rocks. Wiley, London, pp.206-221.
- JOHNSEN, O. and GRICE, J.D. (1999) The crystal chemistry of the eudialyte group. Can. Min., v.37, pp.865-891.
- JOHNSEN, O., FERRARIS, G., GAULT, R.A., GRICE, J.D., KAMPF, A.R. and PEKOV, I.V. (2003) The nomenclature of eudialyte-group minerals. Can. Min., v.43, pp.785-794.
- KOGARKO, L.N. (1980) Ore-forming potential of alkaline magmas. Lithos, v.26, pp.167-175.
- KRAMM, U. and KOGARKO, L.N. (1994) Nd and Sr isotope signatures of the Khibina and Lovozero agpaitic centres, Kola Province, Russia. Lithos, v.32, pp.225-242.
- LE MAITRE, R.W. (2002) Igneous Rocks: A Classification and Glossary of Terms. Cambridge.
- MARKL, G. and BAUMGARTNER, L. (2002) pH changes in peralkaline late-magmatic fluids. Contrib. Mineral. Petrol., v.144, pp.331-346.
- MARKL, G., MARKS, M., SCHWINN, G. and SOMMER, H. (2001) Phase equilibrium constraints on intensive crystallization parameters of the Ilímaussaq Complex, South Greenland. Jour. Petrol., v.42, pp.2231-2258.
- MARKS, M.A.W., HALAMA, R., WENZEL, T. and MARKL, G. (2004) Trace element variations in clinopyroxene and amphibole from alkaline to peralkaline syenites and granites: implications for mineral-melt trace-element partitioning. Chem. Geol., v. 211, pp. 185-215.
- Marks, M.A.W., Hettmann, K., Schilling, J., Frost, B.R. and MARKL, G. (2011) The Mineralogical Diversity of Alkaline Igneous Rocks: Critical Factors for the Transition from Miaskitic to Agpaitic Phase Assemblages. Jour. Petrol., v.52, pp.439-455.
- MITCHELL, R.H. and CHAKRABARTY, A. (2011) Peralkaline nepheline gneiss from Purulia, West Bengal, India: Paragenesis of a new eudialyte group mineral. In: Abstract Volume, Peralk-Carb 2011 pp.100-103.
- MITCHELL, R.H. and LIFEROVICH, R.P. (2006) Subsolidus deuteric/ hydrothermal alteration of eudialyte in lujavrite from the Pilansberg alkaline complex, South Africa. Lithos, v.91, pp.352-372.
- OLIVO, G.R. and WILLIAMS-JONES, A.E. (1999) Hydrothermal REE-rich eudialyte from the Pilanesberg complex, South Africa. Can. Min., v.37, pp.653-663.
- PFAFF, K., KRUMREI, T., MARKS, M., WENZEL, T., RUDOLF, T. and MARKL, G. (2008) Chemical and physical evolution of the lower layered sequence from the syenitic Ilímaussaq intrusion, South Greenland: Implications for the origin of magmatic layering in peralkaline felsic liquids. Lithos, v.106, pp.280-296.
- PFAFF, K., WENZEL, T., SCHILLING, J., MARKS, M. and MARKL, G. (2010) A fast and easy-to-use approach to cation site assignment for eudialyte-group minerals. Neues Jahrbuch für Mineralogie, Abhandlungen, v.187, pp.69-81.
- SCHILLING, J., WU, F.-Y., MCCAMMON, C., WENZEL, T., MARKS, M.A.W., PFAFF, K., JACOB, D.E. and MARKL, G. (2011) The compositional variability of eudialyte-group minerals. Min. Mag., v. 5(1), pp. 7-115.
- SØRENSEN, H. (1992) Agpaitic nepheline syenites: a potential of rare elements. Applied Geochemistry, v.67, pp.417-427.
- SØRENSEN, H. (1997) The agpaitic rocks – an overview. Min. Mag. v. 61, pp. 485 - 498.
- STROMEYER, F. (1819) Summary of meeting 16 December 1819 [Fossilien...] Göttingische gelehrte Anziegen, v.3, pp.1993-2003.
- USSING, N.V. (1912) Geology of the country around Julianehaab, Greenland. Meddelelser om Grønland, v.38, pp.1-376.