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Bambi, A. C. J. M., Costanzo, A., Gonçalves, A. O., Melgarejo, J. C. (2012) Tracing the chemical evolution of primary pyrochlore from plutonic to volcanic carbonatites: the role of fluorine. Mineralogical Magazine, 76 (2) 377-392 doi:10.1180/minmag.2012.076.2.07

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Reference TypeJournal (article/letter/editorial)
TitleTracing the chemical evolution of primary pyrochlore from plutonic to volcanic carbonatites: the role of fluorine
JournalMineralogical Magazine
AuthorsBambi, A. C. J. M.Author
Costanzo, A.Author
Gonçalves, A. O.Author
Melgarejo, J. C.Author
Year2012 (April)Volume76
Issue2
PublisherMineralogical Society
DOIdoi:10.1180/minmag.2012.076.2.07Search in ResearchGate
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Mindat Ref. ID244223Long-form Identifiermindat:1:5:244223:9
GUID0
Full ReferenceBambi, A. C. J. M., Costanzo, A., Gonçalves, A. O., Melgarejo, J. C. (2012) Tracing the chemical evolution of primary pyrochlore from plutonic to volcanic carbonatites: the role of fluorine. Mineralogical Magazine, 76 (2) 377-392 doi:10.1180/minmag.2012.076.2.07
Plain TextBambi, A. C. J. M., Costanzo, A., Gonçalves, A. O., Melgarejo, J. C. (2012) Tracing the chemical evolution of primary pyrochlore from plutonic to volcanic carbonatites: the role of fluorine. Mineralogical Magazine, 76 (2) 377-392 doi:10.1180/minmag.2012.076.2.07
Abstract/NotesAbstractThree Angolan carbonatites were selected to evaluate the change in composition of pyrochlores during magmatic evolution: the Tchivira carbonatites occur in a plutonic complex, the Bonga carbonatites represent hypabyssal carbonatites and the Catanda carbonatites are volcanic in origin. In Tchivira pyrochlore, zoning is poorly developed; fluorine is dominant at the Y site; chemical zoning may arise as a result of substitutions for Nb in the B site; and the rare earth element (REE), U, Th and large-ion lithophile element (LILE) contents are very low. Pyrochlores from Bonga show oscillatory zonation; the F and Na contents are lower than those in the pyrochlores from Tchivira; and as substitution of Na at the A site increases, the Th, U, REE contents and inferred vacancies also increase. Pyrochlores from Catanda display complex textures. They generally have a rounded corroded core, which is mantled by two or three later generations. The core composition is similar to the Bonga pyrochlores. The rims are enriched in Zr, Ta, Th, Ce and U, but depleted in F and Na. In pyrochlores from the Angolan carbonatites, the F and Na contents decrease from plutonic to volcanic settings and there is enrichment of Th, U and REE in the A site and Ta and Zr in the B site. Zoning may be explained by changes in the activity of F, due to the crystallization of fluorite or apatite in the plutonic and hypabyssal carbonatites, or to volatile exsolution in the volcanic carbonatites.

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Torró, L., Villanova, C., Castillo, M., Campeny, M., Gonçalves, A. O., Melgarejo, J. C. (2012) Niobium and rare earth minerals from the Virulundo carbonatite, Namibe, Angola. Mineralogical Magazine, 76 (2) 393-409 doi:10.1180/minmag.2012.076.2.08
Amores Casals S, Bambi A C J M, Gonçalves A O, Melgarejo J C (2014) Mineral chemistry of pyrochlore from the Bonga Carbonatite (Huila, Angola). 21 st meeting of the International Mineralogical Association. p 195
Melgarejo, Joan C., Costanzo, Alessandra, Bambi, Aurora C.J.M., Gonçalves, Antonio O., Neto, Andrés B. (2012) Subsolidus processes as a key factor on the distribution of Nb species in plutonic carbonatites: The Tchivira case, Angola. Lithos, 152. 187-201 doi:10.1016/j.lithos.2012.06.024
Torró, L., Villanova, C., Castillo, M., Gonçalves, A.O., Melgarejo, J.C. (2012) Niobium and rare earth minerals from the Virulundo carbonatite, Namibe, Angola. Mineralogical Magazine, 76 (2) 393-409 doi:10.1180/minmag.2012.076.2.08
de Ignacio, C., Muñoz, M., Sagredo, J. (2012) Carbonatites and associated nephelinites from São Vicente, Cape Verde Islands. Mineralogical Magazine, 76 (2) 311-355 doi:10.1180/minmag.2012.076.2.05
Woolley, A. R., Bailey, D. K. (2012) The crucial role of lithospheric structure in the generation and release of carbonatites: geological evidence. Mineralogical Magazine, 76 (2) 259-270 doi:10.1180/minmag.2012.076.2.02
Amores-Casals, S., Melgarejo, J. C., Bambi, A., Gonçalves, A. O., Morais, E. A., Manuel, J., ... & Molist, J. M. (2019). Lamprophyre-Carbonatite Magma Mingling and Subsolidus Processes as Key Controls on Critical Element Concentration in Carbonatites—The Bonga Complex (Angola). Minerals, 9(10), 601.
Hogarth, D. D., Williams, C. T., Jones, P. (2000) Primary zoning in pyrochlore group minerals from carbonatites. Mineralogical Magazine, 64 (4) 683-697 doi:10.1180/002646100549544
Pearce, N. J. G., Leng, M. J., Emeleus, C. H., Bedford, C. M. (1997) The origins of carbonatites and related rocks from the Grønnedal-Íka Nepheline Syenite complex, South Greenland: C-O-Sr isotope evidence. Mineralogical Magazine, 61 (407) 515-529 doi:10.1180/minmag.1997.061.407.04
James, T. C., McKie, Duncan (1958) The alteration of pyrochlore to columbite in carbonatites in Tanganyika (With Plates XX and XXI.). Mineralogical Magazine and Journal of the Mineralogical Society, 31 (242). 889-900 doi:10.1180/minmag.1958.031.242.01
Stanley, C. J., Roberts, A. C., Harris, D. C. (1994) New data for nagyagite. Mineralogical Magazine, 58 (392) 479-482 doi:10.1180/minmag.1994.058.392.13
 
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