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Loucks, Robert R, Fiorentini, Marco L, Henríquez, Gonzalo J (2020) New Magmatic Oxybarometer Using Trace Elements in Zircon. Journal of Petrology, 61 (3) doi:10.1093/petrology/egaa034

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Reference TypeJournal (article/letter/editorial)
TitleNew Magmatic Oxybarometer Using Trace Elements in Zircon
JournalJournal of Petrology
AuthorsLoucks, Robert RAuthor
Fiorentini, Marco LAuthor
Henríquez, Gonzalo JAuthor
Year2020 (October 10)Volume61
Issue3
PublisherOxford University Press (OUP)
DOIdoi:10.1093/petrology/egaa034Search in ResearchGate
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Mindat Ref. ID532385Long-form Identifiermindat:1:5:532385:6
GUID0
Full ReferenceLoucks, Robert R, Fiorentini, Marco L, Henríquez, Gonzalo J (2020) New Magmatic Oxybarometer Using Trace Elements in Zircon. Journal of Petrology, 61 (3) doi:10.1093/petrology/egaa034
Plain TextLoucks, Robert R, Fiorentini, Marco L, Henríquez, Gonzalo J (2020) New Magmatic Oxybarometer Using Trace Elements in Zircon. Journal of Petrology, 61 (3) doi:10.1093/petrology/egaa034
In(2020, October) Journal of Petrology Vol. 61 (3) Oxford University Press (OUP)
Abstract/NotesAbstract
We derive a novel method for determining the oxidation state of a magma as zircon crystallized, with a standard error of ±0·6 log unit ƒO2, using ratios of Ce, U, and Ti in zircon, without explicit determination of the ionic charge of any of them, and without independent determination of crystallization temperature or pressure or parental melt composition. It yields results in good agreement with oxybarometry on Fe–Ti oxide phenocrysts and hornblende phenocrysts quenched in eruptive I- and A-type dacites and rhyolites, but our zircon oxybarometer is also applicable to slowly cooled plutonic rocks and applicable to detrital and xenocrystic zircons. Zircon/melt partition coefficients of Ce and U vary oppositely with ƒO2 variation in the silicate melt. The Ce/U ratio in zircon also varies with the Ce/U element ratio in the silicate melt. During mafic-to-felsic magmatic differentiation, Ce and U are incorporated mainly in calcium-dominated lattice sites of clinopyroxene, hornblende, apatite, and occasionally titanite and/or allanite, all of which have a similar degree of preference for Ce over U. We employ the U/Ti ratio in zircon and in silicate melt as a magmatic differentiation index. Convergent- and divergent-plate-margin differentiation series consistently follow the relation log (Ce/U) ≈ –0·5 log (U/Ti) + C' in silicate melts of basaltic to rhyolitic composition. That correlation permits thermodynamic derivation of the oxybarometry relation among those elements in zircon: log fO2(sample)−log fO2(FMQ)≈42n+1log[Ce/(Ui×Ti)z]+C, wherein Ui denotes age-corrected initial U content, FMQ represents the reference buffer fayalite + magnetite + quartz, superscript z denotes zircon, and n varies with the average valence of uranium in the zircon’s parental silicate melt. We empirically calibrate this relation, using 1042 analysed zircons in 85 natural populations having independently constrained log ƒO2 in the range FMQ – 4·9 to FMQ + 2·9, to obtain the equation log fO2(sample)−log fO2(FMQ)=3·998(±0·124) log[Ce/(Ui×Ti)z]+2·284(±0·101) with a correlation coefficient R = 0·963 and standard error of 0·6 log unit ƒO2 in calc-alkalic, tholeiitic, adakitic, and shoshonitic, metaluminous to mildly peraluminous and mildly peralkaline melts in the composition range from kimberlite to rhyolite. Thermodynamic assessment and empirical tests indicate that our formulation is insensitive to varying crystallization temperature and pressure at lithospheric conditions. We present a revised equation for Ti-in-zircon thermometry that accounts appropriately for pressure as well as reduced activity of TiO2 and SiO2 in rutile- and quartz-undersaturated melts. It can be used to retrieve absolute values of ƒO2 from values of ΔFMQ obtained from a zircon analysis.

See Also

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Loucks, Robert R., Henríquez, Gonzalo J., Fiorentini, Marco L. (2024) Zircon and Whole-Rock Trace Element Indicators of Magmatic Hydration State and Oxidation State Discriminate Copper Ore-Forming from Barren Arc Magmas. Economic Geology, 119 (3) 511-523 doi:10.5382/econgeo.5071
Loucks, Robert R., Fiorentini, Marco L. (2023) Oxidation of magmas during gain and loss of H2O recorded by trace elements in zircon. Earth and Planetary Science Letters, 622. 118377 doi:10.1016/j.epsl.2023.118377
Barker, S. J., Wilson, C. J. N., Smith, E. G. C., Charlier, B. L. A., Wooden, J. L., Hiess, J., Ireland, T. R. (2014) Post-supereruption Magmatic Reconstruction of Taupo Volcano (New Zealand), as Reflected in Zircon Ages and Trace Elements. Journal of Petrology, 55 (8) 1511-1533 doi:10.1093/petrology/egu032
Loucks, Robert R., Fiorentini, Marco L. (2023) Early zircon saturation in adakitic magmatic differentiation series and low Zr content of porphyry copper magmas. Mineralium Deposita, 58 (8) 1381-1393 doi:10.1007/s00126-023-01208-5
Chamberlain, K. J., Wilson, C. J. N., Wooden, J. L., Charlier, B. L. A., Ireland, T. R. (2014) New Perspectives on the Bishop Tuff from Zircon Textures, Ages and Trace Elements. Journal of Petrology, 55 (2) 395-426 doi:10.1093/petrology/egt072
Grimes, C. B., Wooden, J. L., Cheadle, M. J., John, B. E. (2015) “Fingerprinting” tectono-magmatic provenance using trace elements in igneous zircon. Contributions to Mineralogy and Petrology, 170 (5) doi:10.1007/s00410-015-1199-3
Loucks, Robert R., Fiorentini, Marco L., Rohrlach, Bruce D. (2018) Divergent T–ƒO2 paths during crystallisation of H2O-rich and H2O-poor magmas as recorded by Ce and U in zircon, with implications for TitaniQ and TitaniZ geothermometry. Contributions to Mineralogy and Petrology, 173 (12) doi:10.1007/s00410-018-1529-3
Loucks, Robert R., Fiorentini, Marco L., Rohrlach, Bruce D. (2019) Correction to: Divergent T–ƒO2 paths during crystallisation of H2O-rich and H2O-poor magmas as recorded by Ce and U in zircon, with implications for TitaniQ and TitaniZ geothermometry. Contributions to Mineralogy and Petrology, 174 (1) doi:10.1007/s00410-018-1541-7
Rowe, Michael C., Kent, Adam J. R., Nielsen, Roger L. (2009) Subduction Influence on Oxygen Fugacity and Trace and Volatile Elements in Basalts Across the Cascade Volcanic Arc. Journal of Petrology, 50 (1) 61-91 doi:10.1093/petrology/egn072
Pupin, J P (2024) Zircon Typology: a Synthesis. Applications to Magmatic, Metamorphic and Sedimentary Rocks. Journal of Petrology, 65 (11). doi:10.1093/petrology/egae111
McBIRNEY, A. R. (2002) The Skaergaard Layered Series. Part VI. Excluded Trace Elements. Journal of Petrology, 43 (3) 535-556 doi:10.1093/petrology/43.3.535
 
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