Extreme P-, Bi-, Nb-, Sc-, U- and F-rich zircon from fractionated perphosphorous granites: The peraluminous Podlesí granite system, Czech Republic期刊界 All Journals 搜尽天下杂志传播学术成果专业期刊搜索期刊信息化学术搜索

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Extreme P-, Bi-, Nb-, Sc-, U- and F-rich zircon from fractionated perphosphorous granites: The peraluminous Podlesí granite system, Czech Republic

Authors:	Karel Breiter Hans-Jürgen Frster Radek &#x;koda

Institution:	^aCzech Geological Survey, Geologická 6, CZ-15200 Praha 5, Czech Republic ^bInstitute of Earth Sciences, University of Potsdam, P.O. Box 601553, D-14415 Potsdam, Germany ^cInstitute of Earth Sciences, Masaryk University, Kotlá?ská 2, CZ-61137 Brno, Czech Republic

Abstract:	The strongly peraluminous and P-rich, protolithionite and zinnwaldite leucogranites from Podlesí, western Kru?né Hory Mts., Czech Republic, contain accessory zircon with extraordinary enrichment of several elements, which constitute trace elements in common zircon. Elements showing a not yet reported anomalous enrichment include P (up to 20.2 wt.% P₂O₅; equivalent to 0.60 apfu, formula calculated on the basis of 4 oxygen atoms), Bi (up to 9.0 wt.% Bi₂O₃; 0.086 apfu), Nb (up to 6.7 wt.% Nb₂O₅, 0.12 apfu), Sc (up to 3.45 wt.% Sc₂O₃; 0.10 apfu), U (up to 14.8 wt.% UO₂; 0.12 apfu) and F (up to 3.81 wt.% F; 0.42 apfu). Strong enrichment of P preferentially involved the berlinite-type substitution (2 Si⁴⁺ P⁵⁺ + Al³⁺) implying that significant Al may enter the Si position in zircon. Incorporation of other exotic elements is primarily governed by the xenotime (Si⁴⁺ + Zr⁴⁺ P⁵⁺ + Y³⁺), pretulite (Sc³⁺ + P⁵⁺ Zr⁴⁺ + Si⁴⁺), brabantite-type (Ca²⁺ + (U, Th)⁴⁺ + 2P⁵⁺ 2Zr⁴⁺ + 2Si⁴⁺), and ximengite-type (Bi³⁺ + P⁵⁺ Zr⁴⁺ + Si⁴⁺) substitution reactions. One part of the anomalous zircons formed late-magmatically, from a strongly peraluminous, P–F–U-rich hydrous residual melt that gave rise to the zinnwaldite granite. Interaction with aggressive residual fluids and metamictization have further aided in element enrichment or depletion, particularly in altered parts of zircon contained in the protolithionite granite. Most of the zircon from F-rich greisens have a composition close to endmember ZrSiO₄ and are chemically distinct from zircon in its granite parent. This discrepancy implies that at Podlesí, granitic zircon became unstable and completely dissolved during greisenization. Part of the mobilized elements was reprecipitated in newly grown, hydrothermal zircon.

Keywords:	Zircon Phosphorus Niobium Uranium Bismuth Scandium Fluorine Solid solution Peraluminous granites
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