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Significance of apatite REE depletion and monazite inclusions in the brecciated Se–Chahun iron oxide–apatite deposit, Bafq district, Iran: Insights from paragenesis and geochemistry

Bonyadi, Zahra ; Davidson, Garry J. ; Mehrabi, Behzad ; Meffre, Sebastien ; Ghazban, Fereydoun

Chemical geology, 2011-02, Vol.281 (3), p.253-269 [Periódico revisado por pares]

Elsevier B.V

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  • Título:
    Significance of apatite REE depletion and monazite inclusions in the brecciated Se–Chahun iron oxide–apatite deposit, Bafq district, Iran: Insights from paragenesis and geochemistry
  • Autor: Bonyadi, Zahra ; Davidson, Garry J. ; Mehrabi, Behzad ; Meffre, Sebastien ; Ghazban, Fereydoun
  • Assuntos: aluminum ; Apatite ; Bafq Mineral Province ; biotite ; calcite ; Computational fluid dynamics ; Deposits ; Fluid flow ; Fluids ; geochemistry ; hematite ; Iran ; iron ; Iron oxides ; Iron oxide–apatite deposit ; leaching ; magnesium ; Magnetite ; manganese ; Monazite ; Pb-isotopes ; Rare earth elements ; sodium ; Texture
  • É parte de: Chemical geology, 2011-02, Vol.281 (3), p.253-269
  • Notas: http://dx.doi.org/10.1016/j.chemgeo.2010.12.013
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  • Descrição: The Se–Chahun magnetite–apatite deposit (Bafq district, central Iran) comprises several orebodies with large-scale replacement and brecciation textures, and a sodic–calcic alteration envelope. Such members of the iron-oxide copper–gold (IOCG) deposit family commonly exhibit REE enrichment, but the source and evolution of the REE component is arguable. In the Anomaly X orebody, semi-massive ilmenite-rich magnetite and coarse REE-rich fluorapatite formed at 510 ± 8 Ma (U–Pb LA-ICPMS age), at the end of the main regional sodic magmatic event (525 ± 7 Ma). Prior to a major brecciation, a metasomatic event removed Ti and Al from magnetite grain boundaries, and leached primary fluorapatite (BSE-bright) of LREE, Y, Na, Cl, Mg, Mn and Fe, leaving BSE-dark apatite that contained LREE-rich monazite and co-existing vapor- and liquid-dominated fluid inclusions. Subsequent brecciation and hydrothermal infill produced a matrix dominated by actinolite, K-feldspar, biotite, chlorite, calcite, hematite, rutile, and titanite, but apatite was not further metasomatized. It is concluded that P, REE, Ti, Al and Fe were readily transported in the early sodic–calcic fluids, but P and the REE had very restricted mobility (mm's to cm's) in the CO 2–K–Cl-rich fluids responsible for apatite metasomatism. A role for fluid over-pressuring as a means of increasing the efficacy of apatite REE leaching is circumstantially suggested by the observation that the metasomatic event was terminated by tensile failure. Overall, a case is emerging for fluid-induced nucleation of monazite, and accompanying apatite REE depletion, to be included as a typical but subtle paragenetic feature within the iron oxide–apatite deposit model. ► Apatite metasomatism occurs due to fluid over-pressuring immediately prior to brecciation. ► Apatite metasomatism is the first consequence of a shift to K-rich fluids in the system. ► The genetic affinity of the apatites is still recognisable on a Y–Sr classification diagram despite significant removal of LREE. ► Apatite first formed at 510 ± 8 Ma, at the end of or after regional sodic granite intrusion in the BMP. ► Pre-brecciation metasomatism leached the margins of magnetite crystals of Ti and Al.
  • Editor: Elsevier B.V
  • Idioma: Inglês
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  • Realização: ABCD-USP USP   Logos de Redes Sociais: Freepik

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