Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-26T09:10:24.221Z Has data issue: false hasContentIssue false

A mechanism for Nb incorporation in rutile and application of Zr-in-rutile thermometry: A case study from granulite facies paragneisses of the Mogok metamorphic belt, Myanmar

Published online by Cambridge University Press:  26 January 2018

Maw Maw Win
Affiliation:
Department of Earth and Planetary Sciences, Graduate School of Environmental Studies, Nagoya University, Nagoya 464-8601, Japan
M. Enami*
Affiliation:
Institute for Space–Earth Environmental Research, Nagoya University, Nagoya 464-8601, Japan
T. Kato
Affiliation:
Institute for Space–Earth Environmental Research, Nagoya University, Nagoya 464-8601, Japan
Ye Kyaw Thu
Affiliation:
Department of Earth and Planetary Sciences, Graduate School of Environmental Studies, Nagoya University, Nagoya 464-8601, Japan
*

Abstract

Rutile grains occur extensively in host phases of biotite and quartz-feldspar aggregate in high-temperature paragneisses of the Mogok metamorphic belt of Myanmar. They occur as an isolated phase and sometimes show intergrowth texture with ilmenite. Most rutile grains contain up to 3.7 wt.% Nb2O5, which shows positive correlations with Fe and trivalent elements. Niobium substitutes for Ti by a coupled substitution with the trivalent cations (M3+) of Nb5+M3+Ti4+-2. Fine-grained rutile grains included in ilmenite are distinctly poor in Nb (<0.1 wt.% as Nb2O5) and contain Fe of 1.7–3.2 wt.% as Fe2O3, suggesting vacancybearing substitution of Fe3+4 Ti4+-3–1, where □ indicates a vacancy. The rutile grains in the felsic phases contain high Zr contents of up to 4200 ppm, suggesting equilibrium temperatures over 800°C using the Ti-in-rutile geothermometer. These high-temperature conditions are consistent with those estimated by conventional methods reported in the literature and suggest widespread occurrences of the upperamphibolite and granulite facies metamorphic rocks in the middle segment of the Mogok metamorphic belt. In contrast, the Zr contents of rutile grains in biotite are usually <1000 ppm, implying equilibrium temperatures lower than 750°C. Most of the rutile grains poorer in Zr might have been included in biotite and were isolated from the zircon-bearing system during an early stage of prograde metamorphism. Some other rutile grains poorer in Zr might have been an exsolved phase from Ti-rich biotite during retrograde metamorphism, which was furthered by the infiltration of metamorphic fluid under lower-amphibolite facies conditions.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2017

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

*

Present address: Yadanabon University, Amarapura, Mandalay, Myanmar

References

Bertrand, G., Rangin, C., Maluski, H., Han, T.A., Thein, M., Myint, O., Maw,W. and Lwin, S. (1999) Cenozoic metamorphism along the Shan scarp (Myanmar): evidences for ductile shear along the Sagaing fault or the northward migration of the eastern Himalayan syntaxis? Geophysical Research Letters, 26, 915918.Google Scholar
J.F.W., Bowles, Howie, R.A., Vaughan, D.J. and Zussman, J. (2011) Non-Silicates: Oxides, Hydroxides and Sulphides (Second Edition). Rock-Forming Minerals, 5A. The Geological Society, London.Google Scholar
Cempírek, J., Houzar, S. and Novák, M. (2008) Complexly zoned niobian titanite from hedenbergite skarn at Pisek, Czech Republic, constrained by substitutions Al(Nb,Ta)Ti–2, Al(F,OH)(TiO)–1 and SnTi–1. Mineralogical Magazine, 72, 12931305.CrossRefGoogle Scholar
Černý, P. and Chapman, R. (2001) Exsolution and breakdown of scandian and tungstenian Nb-Ta-Ti- Fe-Mn phases in niobian rutile. Canadian Mineralogist, 39, 93101.Google Scholar
Černý, P., Chapman, R., Simmons, W.B. and Chackowsky, L.E. (1999) Niobian rutile from the McGuire granitic pegmatite, Park County, Colorado: Solid solution, exsolution, and oxidation. American Mineralogist, 84, 754763.CrossRefGoogle Scholar
Condie, K.C. (1993) Chemical composition and evolution of the upper continental crust: Contrasting results from surface samples and shales. Chemical Geology, 104, 137.CrossRefGoogle Scholar
Dymek, R.F. (1983) Fe-Ti oxides in the Malene Supracrustals and the occurrence of Nb-rich rutile. Rapport Grønlands geologiske Undersøgelse, 112, 8394.Google Scholar
Ewing, T.A., Hermann, J. and Rubatto, D. (2013) The robustness of the Zr-in-rutile and Ti-in-zircon thermometers during high-temperature metamorphism (Ivrea- Verbano Zone, northern Italy). Contributions to Mineralogy and Petrology, 165, 757779.CrossRefGoogle Scholar
Ferry, J.M. andWatson, E.B. (2007) New thermodynamic models and revised calibrations for the Ti-in-zircon and Zr-in-rutile thermometers. Contributions to Mineralogy and Petrology, 54, 429437.CrossRefGoogle Scholar
Foley, S.F., Barth, M.G. and Jenner, G.A. (2000) Rutile/ melt partition coefficients for trace elements and an assessment of the influence of rutile on the trace element characteristics of subduction zone magmas. Geochimica et Cosmochimica Acta, 64, 933938.CrossRefGoogle Scholar
Gromet, L.P., Dymek, R.F., Haskin, L.A. and Korotev, R. L. (1984) The “North American shale composite“: Its composition, major and trace element characterstics. Geochimica et Cosmochimica Acta, 48, 24692482.CrossRefGoogle Scholar
Hirtopanu, P., Fairhurst, R.J. and Jakab, G. (2015) Niobian rutile and its associations at Jolotca, Ditrau alkaline intrusive massif, east Carpathians, Romania. Proceedings of Romania Academy, Series B, 17, 3955.Google Scholar
Kato, T. (2005) New accurate Bence-Albee α-factors for oxides and silicates calculated from the PAP correction procedure. Geostandrds and Geoanalytical Research, 29, 8394.CrossRefGoogle Scholar
Khodos, M.Y., Belysheva, G.M. and Krivosheev, N.V. (1988) Solid solutions with the rutile structure in the TiO2–Nb2O5 system. Russian Journal of Inorganic Chemistry, 33, 604606.Google Scholar
Klemme, S., Prowatke, S., Hametner, K. and Günther, D. (2005) Partitioning of trace elements between rutile and silicate melts: Implications for subduction zones. Geochimica et Cosmochimica Acta, 69, 23612371.CrossRefGoogle Scholar
Korolev, N.M., Marin, Y.B., Nikitina, L.P., Zinchenko, V. N. and Chissupa, H.M. (2014) High-Nb rutile from upper mantle eclogite xenoliths of the diamondbearing kimberlite pipe Catoca (Angola). Doklady Earth Sciences, 454, 5053.CrossRefGoogle Scholar
Luvizotto, G.L. and Zack, T. (2009) Nb and Zr behavior in rutile during high-grade metamorphism and retrogression: An example from the Ivrea-Verbano Zone. Chemical Geology, 261, 303317.CrossRefGoogle Scholar
Luvizotto, G.L., Zack, T., Triebold, S. and von Eynatten, H. (2009) Rutile occurrence and trace element behavior in medium-grade metasedimentary rocks: example from the Erzgebirge, Germany. Mineralogy and Petrology, 97, 233249.CrossRefGoogle Scholar
Maw Maw Win, Enami, M. and Kato, T. (2016) Metamorphic conditions and CHIME monazite ages of Late Eocene to Late Oligocene high-temperature Mogok metamorphic rocks in central Myanmar. Journal of Asian Earth Sciences, 117, 304316.Google Scholar
Meinhold, G. (2010) Rutile and its applications in earth sciences. Earth-Science Reviews, 102, 128.CrossRefGoogle Scholar
Meyer, M., John, T., Brandt, S. and Klemd, R. (2011) Trace element composition of rutile and the application of Zr-in-rutile thermometry to UHT metamorphism (EpupaComplex,NWNamibia). Lithos, 126, 388401.CrossRefGoogle Scholar
Mitchell, A.H.G., Myint Thein Htay, Htun, K.M., Myint Naing Win, Thura Oo and Tin Hlaing. (2007) Rock relationships in the Mogok metamorphic belt, Tatkon to Mandalay, central Myanmar. Journal of Asian Earth Sciences, 29, 891910.CrossRefGoogle Scholar
Oberti, R., Smith, D.C., Rossi, G. and Caucia, F. (1991) The crystal-chemistry of high-aluminium titanites. European Journal of Mineralogy, 3, 777792.CrossRefGoogle Scholar
Pape, J., Mezger, K. and Robyr, M. (2016) A systematic evaluation of the Zr-in-rutile thermometer in ultra-high temperature (UHT) rocks. Contributions to Mineralogy and Petrology, 171(5), 130.Google Scholar
Rezvukhin, D.I., Malkovets, V.G., Sharygin, I.S., Kuzmin, D.V., Litasov, K.D., Gibsher, A.A., Pokhilenko, N.P. and Sobolev, N.V. (2016) Inclusions of Cr- and Cr-Nb-Rutile in pyropes from the Internatsionalnaya kimberlite pipe, Yakutia. Doklady Earth Sciences, 466, 173176.CrossRefGoogle Scholar
Searle, M.P., Noble, S.R., Cottle, J.M., Waters, D.J., Mitchell, A.H.G., Tin Hlaing and Horstwood, M.S.A. (2007) Tectonic evolution of the Mogok metamorphic belt, Burma (Myanmar) constrained by U-Th-Pb dating of metamorphic and magmatic rocks. Tectonics, 26, TC3014.Google Scholar
Smith, D.C. (1988) A review of the peculiar mineralogy of the “Norwegian-eclogite province,” with crystal-chemical, petrological, geochemical and geodynamical notes and an extensive bibliography. Pp. 1206 in: Eclogites and Eclogite-Facies Rocks (D.C. Smith, editor). Developments in Petrology, 12. Elsevier, Amsterdam.Google Scholar
Smith, D.C. and Perseil, E.A. (1997) Sb-rich rutile in the manganese concentrations at St. Marcel-Praborna, Aosta Valley, Italy: petrology and crystal-chemistry. Mineralogical Magazine, 61, 655669.CrossRefGoogle Scholar
Sobolev, N.V., Logvinova, A.M., Lavrent’ev, Y.G., Karmanov, N.S., Usova, L.V., Koz’menko, O.A. and Ragozin, A.L. (2011) Nb-rutile from eclogite microxenolith of the Zagadochnaya kimberlite pipe. Doklady Earth Sciences, 439, 970973.CrossRefGoogle Scholar
Tan, W., Wang, C.Y., He, H., Xing, C., Liang, X. and Dong, H. (2015) Magnetite-rutile symplectite derived from ilmenite-hematite solid solution in the Xinjie Fe- Ti oxide-bearing, mafic-ultramafic layered intrusion (SW China). American Mineralogist, 100, 23482351.CrossRefGoogle Scholar
Taylor, S.R. and McLennan, S.M. (1988) The significance of the rare earths in geochemistry and cosmochemistry. Pp. 485578 in: Handbook on the Physics and Chemistry of Rare Earths, 11. (Gschneider, K.A., Jr. and Eyring, L., editors). Elsevier, Amsterdam.Google Scholar
Tollo, R.P. and Haggerty, S.E. (1987) Nb-Cr-rutile in the Orapa kimberlite, Botswana. Canadian Mineralogist, 25, 251264.Google Scholar
Tomkins, H.S., Powell, R. and Ellis, D.J. (2007) The pressure dependence of the zirconium-in-rutile thermometer. Journal of Metamorphic Geology, 25, 703713.CrossRefGoogle Scholar
Villaseca, C., Orejana, D. and Paterson, B.A. (2007) Zr– LREE rich minerals in residual peraluminous granulites, another factor in the origin of low Zr–LREE granitic melts? Lithos, 375386.Google Scholar
Vlassopoulos, D., Rossman, G.R. and Haggerty, S.E. (1993) Coupled substitution of H and minor elements in rutile and the implications of high OH contents in Nb-and Cr-rich rutile from the upper mantle. American Mineralogist, 78, 11811191.Google Scholar
Watson, E.B., Wark, D.A. and Thomas, J.B. (2006) Crystallization thermometers for zircon and rutile. Contributions to Mineralogy and Petrology, 151, 413433.CrossRefGoogle Scholar
Yamamoto, K. and Morishita, T. (1997) Preparation of standard composites for trace element analysis by X-ray fluorescence. Journal of Geological Society of Japan, 103, 10371045 (in Japanese with English abstract).CrossRefGoogle Scholar
Thu, Ye Kyaw, MawMawWin, Enami, M. and Tsuboi, M. (2016) Ti-rich biotite in spinel and quartz-bearing paragneiss and related rocks from the Mogok metamorphic belt, central Myanmar. Journal of Mineralogical and Petrological Sciences, 111, 270282.Google Scholar
Thu, Ye Kyaw, Enami, M., Kato, T. and Tsuboi, M. (2017) Granulite facies paragneisses from the middle segment of the Mogok metamorphic belt, central Myanmar. Journal of Mineralogical and Petrological Sciences, 112, 119.Google Scholar
Yonemura, K., Osanai, Y., Nakano, N., Adachi, T., Charusiri, P. and Tun Naing Zaw. (2013) EPMA U-Th-Pb monazite dating of metamorphic rocks from the Mogok Metamorphic Belt, central Myanmar. Journal of Mineralogical and Petrological Sciences, 108, 184188.CrossRefGoogle Scholar
Zack, T., Kronz, A., Foley, S.F. and Rivers, T. (2002) Trace element abundances in rutiles from eclogites and associated garnet mica schists. Chemical Geology, 184, 97122.CrossRefGoogle Scholar
Zack, T., Moraes, R. and Kronz, A. (2004) Temperature dependence of Zr in rutile: empirical calibration of a rutile thermometer. Contributions to Mineralogy and Petrology, 148, 471488.CrossRefGoogle Scholar