Zircon melt inclusions in mafic and felsic rocks of the Bushveld Complex: Constraints for zircon crystallization temperatures and partition coefficients

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External Research Organisations

  • Goethe University Frankfurt
  • University of the Witwatersrand
  • University of Freiburg
  • Heidelberg University
  • Karlsruhe Institute of Technology (KIT)
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Original languageEnglish
Pages (from-to)158-181
Number of pages24
JournalGeochimica et Cosmochimica Acta
Volume289
Early online date4 Sept 2020
Publication statusPublished - 15 Nov 2020

Abstract

Melt inclusions in zircon represent time capsules, which provide deep insights into igneous rock formation including timing, physicochemical conditions, and the compositional evolution of cogenetic magmas with respect to major, trace, and volatile elements. However, their full potential as petrogenetic indicators, in particular their usability and consistency as geothermometers, is poorly investigated. Therefore, we present new mineralogical and chemical data for recrystallized and homogenized melt inclusions and host zircon from different mafic and felsic rocks of the Bushveld Complex (BC), South Africa. Samples include rutile-bearing cumulate rocks of the Marginal and Critical zones, as well as rutile-free, magnetite-ilmenite-titanite-bearing diorites and granites of the Upper Zone, Rashoop Granophyre and Lebowa Granite Suite. All melt inclusions, irrespective of rock type, have rhyolitic compositions with SiO2 contents ranging from 65 to 78 wt.%, and H2O from 1.6 to 4.0 wt.%, whereas trace element contents differ systematically between rock types. In rutile-bearing mafic rocks, melt inclusions commonly show higher Ti contents (>800 ppm), higher Th/U ratios (up to 38), and lower REE contents (ƩREE < 150 ppm) compared to those in rutile-free mafic and felsic rocks (Ti < 800 ppm; Th/U < 5; ƩREE > 150 ppm). Liquidus temperatures of melt inclusions obtained from normative Qz-Ab-Or and rhyolite-MELTS modelling indicate melt entrapment mostly at 930–850 °C (at 200 MPa), tailing down in some samples to 700 °C. For rutile-bearing rocks, these temperatures overlap with those obtained by TiO2-in-melt and Ti-in-zircon geothermometry. For all rutile-free mafic and felsic rocks, reduced TiO2 activities of aTiO2 ∼ 0.3 are required for Ti-in-zircon geothermometry, and TiO2rutile ∼ 30 wt.% for TiO2 saturation geothermometry, to match temperatures from other geothermometers. Furthermore, partition coefficients obtained from melt inclusion - host zircon pairs are within error identical for mafic and felsic rocks and also reveal no systematic dependency on melt inclusion size, composition and entrapment temperature. The results of this study demonstrate that melt inclusions in zircon are a powerful tool for geothermometry and to constrain magma compositions, H2O contents, and TiO2 activities, which are critical for the understanding of magmatic processes shaping Earth's crust.

Keywords

    Bushveld Complex, Melt inclusions, Partition coefficients, Thermometry, Zircon

ASJC Scopus subject areas

Cite this

Zircon melt inclusions in mafic and felsic rocks of the Bushveld Complex: Constraints for zircon crystallization temperatures and partition coefficients. / Gudelius, D.; Zeh, A.; Almeev, Renat R. et al.
In: Geochimica et Cosmochimica Acta, Vol. 289, 15.11.2020, p. 158-181.

Research output: Contribution to journalArticleResearchpeer review

Gudelius D, Zeh A, Almeev RR, Wilson AH, Fischer LA, Schmitt AK. Zircon melt inclusions in mafic and felsic rocks of the Bushveld Complex: Constraints for zircon crystallization temperatures and partition coefficients. Geochimica et Cosmochimica Acta. 2020 Nov 15;289:158-181. Epub 2020 Sept 4. doi: 10.1016/j.gca.2020.08.027
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title = "Zircon melt inclusions in mafic and felsic rocks of the Bushveld Complex: Constraints for zircon crystallization temperatures and partition coefficients",
abstract = "Melt inclusions in zircon represent time capsules, which provide deep insights into igneous rock formation including timing, physicochemical conditions, and the compositional evolution of cogenetic magmas with respect to major, trace, and volatile elements. However, their full potential as petrogenetic indicators, in particular their usability and consistency as geothermometers, is poorly investigated. Therefore, we present new mineralogical and chemical data for recrystallized and homogenized melt inclusions and host zircon from different mafic and felsic rocks of the Bushveld Complex (BC), South Africa. Samples include rutile-bearing cumulate rocks of the Marginal and Critical zones, as well as rutile-free, magnetite-ilmenite-titanite-bearing diorites and granites of the Upper Zone, Rashoop Granophyre and Lebowa Granite Suite. All melt inclusions, irrespective of rock type, have rhyolitic compositions with SiO2 contents ranging from 65 to 78 wt.%, and H2O from 1.6 to 4.0 wt.%, whereas trace element contents differ systematically between rock types. In rutile-bearing mafic rocks, melt inclusions commonly show higher Ti contents (>800 ppm), higher Th/U ratios (up to 38), and lower REE contents (ƩREE < 150 ppm) compared to those in rutile-free mafic and felsic rocks (Ti < 800 ppm; Th/U < 5; ƩREE > 150 ppm). Liquidus temperatures of melt inclusions obtained from normative Qz-Ab-Or and rhyolite-MELTS modelling indicate melt entrapment mostly at 930–850 °C (at 200 MPa), tailing down in some samples to 700 °C. For rutile-bearing rocks, these temperatures overlap with those obtained by TiO2-in-melt and Ti-in-zircon geothermometry. For all rutile-free mafic and felsic rocks, reduced TiO2 activities of aTiO2 ∼ 0.3 are required for Ti-in-zircon geothermometry, and TiO2rutile ∼ 30 wt.% for TiO2 saturation geothermometry, to match temperatures from other geothermometers. Furthermore, partition coefficients obtained from melt inclusion - host zircon pairs are within error identical for mafic and felsic rocks and also reveal no systematic dependency on melt inclusion size, composition and entrapment temperature. The results of this study demonstrate that melt inclusions in zircon are a powerful tool for geothermometry and to constrain magma compositions, H2O contents, and TiO2 activities, which are critical for the understanding of magmatic processes shaping Earth's crust.",
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author = "D. Gudelius and A. Zeh and Almeev, {Renat R.} and Wilson, {A. H.} and Fischer, {L. A.} and Schmitt, {A. K.}",
note = "Funding Information: DG and AZ thank the Deutsche Forschungsgemeinschaft (DFG grant ZE 424/12-1), and Linda Marko, Richard Albert Roper and Axel Gerdes (Frankfurt Isotope and Element Research Center (FIERCE), Goethe-University Frankfurt, Germany) for support with sample preparation and LA-ICP-MS analyses. RA thanks DFG for support of the experimental program (DFG grant KO1723/20). We are grateful to Robert Balzer, Stefan Linsler, Florian Pohl and Christian Singer for the help with experiments. All authors are also indebted to late Joe Aphanane (University of the Witwatersrand) for zircon separation and preparation, David Schiller (Salzburg University, Austria) for support during thermodynamic modelling as well as to Samancor Chrome and Bokoni Platinum Mine Proprietary Ltd. for support during sampling. This work has greatly benefited from detailed reviews by Emilie Bruand, Jill VanTongeren and N. Alex Zirakparvar.",
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Download

TY - JOUR

T1 - Zircon melt inclusions in mafic and felsic rocks of the Bushveld Complex

T2 - Constraints for zircon crystallization temperatures and partition coefficients

AU - Gudelius, D.

AU - Zeh, A.

AU - Almeev, Renat R.

AU - Wilson, A. H.

AU - Fischer, L. A.

AU - Schmitt, A. K.

N1 - Funding Information: DG and AZ thank the Deutsche Forschungsgemeinschaft (DFG grant ZE 424/12-1), and Linda Marko, Richard Albert Roper and Axel Gerdes (Frankfurt Isotope and Element Research Center (FIERCE), Goethe-University Frankfurt, Germany) for support with sample preparation and LA-ICP-MS analyses. RA thanks DFG for support of the experimental program (DFG grant KO1723/20). We are grateful to Robert Balzer, Stefan Linsler, Florian Pohl and Christian Singer for the help with experiments. All authors are also indebted to late Joe Aphanane (University of the Witwatersrand) for zircon separation and preparation, David Schiller (Salzburg University, Austria) for support during thermodynamic modelling as well as to Samancor Chrome and Bokoni Platinum Mine Proprietary Ltd. for support during sampling. This work has greatly benefited from detailed reviews by Emilie Bruand, Jill VanTongeren and N. Alex Zirakparvar.

PY - 2020/11/15

Y1 - 2020/11/15

N2 - Melt inclusions in zircon represent time capsules, which provide deep insights into igneous rock formation including timing, physicochemical conditions, and the compositional evolution of cogenetic magmas with respect to major, trace, and volatile elements. However, their full potential as petrogenetic indicators, in particular their usability and consistency as geothermometers, is poorly investigated. Therefore, we present new mineralogical and chemical data for recrystallized and homogenized melt inclusions and host zircon from different mafic and felsic rocks of the Bushveld Complex (BC), South Africa. Samples include rutile-bearing cumulate rocks of the Marginal and Critical zones, as well as rutile-free, magnetite-ilmenite-titanite-bearing diorites and granites of the Upper Zone, Rashoop Granophyre and Lebowa Granite Suite. All melt inclusions, irrespective of rock type, have rhyolitic compositions with SiO2 contents ranging from 65 to 78 wt.%, and H2O from 1.6 to 4.0 wt.%, whereas trace element contents differ systematically between rock types. In rutile-bearing mafic rocks, melt inclusions commonly show higher Ti contents (>800 ppm), higher Th/U ratios (up to 38), and lower REE contents (ƩREE < 150 ppm) compared to those in rutile-free mafic and felsic rocks (Ti < 800 ppm; Th/U < 5; ƩREE > 150 ppm). Liquidus temperatures of melt inclusions obtained from normative Qz-Ab-Or and rhyolite-MELTS modelling indicate melt entrapment mostly at 930–850 °C (at 200 MPa), tailing down in some samples to 700 °C. For rutile-bearing rocks, these temperatures overlap with those obtained by TiO2-in-melt and Ti-in-zircon geothermometry. For all rutile-free mafic and felsic rocks, reduced TiO2 activities of aTiO2 ∼ 0.3 are required for Ti-in-zircon geothermometry, and TiO2rutile ∼ 30 wt.% for TiO2 saturation geothermometry, to match temperatures from other geothermometers. Furthermore, partition coefficients obtained from melt inclusion - host zircon pairs are within error identical for mafic and felsic rocks and also reveal no systematic dependency on melt inclusion size, composition and entrapment temperature. The results of this study demonstrate that melt inclusions in zircon are a powerful tool for geothermometry and to constrain magma compositions, H2O contents, and TiO2 activities, which are critical for the understanding of magmatic processes shaping Earth's crust.

AB - Melt inclusions in zircon represent time capsules, which provide deep insights into igneous rock formation including timing, physicochemical conditions, and the compositional evolution of cogenetic magmas with respect to major, trace, and volatile elements. However, their full potential as petrogenetic indicators, in particular their usability and consistency as geothermometers, is poorly investigated. Therefore, we present new mineralogical and chemical data for recrystallized and homogenized melt inclusions and host zircon from different mafic and felsic rocks of the Bushveld Complex (BC), South Africa. Samples include rutile-bearing cumulate rocks of the Marginal and Critical zones, as well as rutile-free, magnetite-ilmenite-titanite-bearing diorites and granites of the Upper Zone, Rashoop Granophyre and Lebowa Granite Suite. All melt inclusions, irrespective of rock type, have rhyolitic compositions with SiO2 contents ranging from 65 to 78 wt.%, and H2O from 1.6 to 4.0 wt.%, whereas trace element contents differ systematically between rock types. In rutile-bearing mafic rocks, melt inclusions commonly show higher Ti contents (>800 ppm), higher Th/U ratios (up to 38), and lower REE contents (ƩREE < 150 ppm) compared to those in rutile-free mafic and felsic rocks (Ti < 800 ppm; Th/U < 5; ƩREE > 150 ppm). Liquidus temperatures of melt inclusions obtained from normative Qz-Ab-Or and rhyolite-MELTS modelling indicate melt entrapment mostly at 930–850 °C (at 200 MPa), tailing down in some samples to 700 °C. For rutile-bearing rocks, these temperatures overlap with those obtained by TiO2-in-melt and Ti-in-zircon geothermometry. For all rutile-free mafic and felsic rocks, reduced TiO2 activities of aTiO2 ∼ 0.3 are required for Ti-in-zircon geothermometry, and TiO2rutile ∼ 30 wt.% for TiO2 saturation geothermometry, to match temperatures from other geothermometers. Furthermore, partition coefficients obtained from melt inclusion - host zircon pairs are within error identical for mafic and felsic rocks and also reveal no systematic dependency on melt inclusion size, composition and entrapment temperature. The results of this study demonstrate that melt inclusions in zircon are a powerful tool for geothermometry and to constrain magma compositions, H2O contents, and TiO2 activities, which are critical for the understanding of magmatic processes shaping Earth's crust.

KW - Bushveld Complex

KW - Melt inclusions

KW - Partition coefficients

KW - Thermometry

KW - Zircon

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JO - Geochimica et Cosmochimica Acta

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