Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas

Research output: Contribution to journalArticleResearchpeer review

Authors

  • S. Kommescher
  • F. Kurzweil
  • R. O.C. Fonseca
  • L. J.A. Rzehak
  • S. V. Hohl
  • M. Kirchenbaur
  • S. Schuth
  • P. Sprung
  • C. Münker

Research Organisations

External Research Organisations

  • University of Cologne
  • Ruhr-Universität Bochum
  • Paul Scherrer Institut (PSI)
  • Tongji University
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Details

Original languageEnglish
Article numbere2022GC010840
Number of pages25
JournalGeochemistry, Geophysics, Geosystems
Volume24
Issue number8
Publication statusPublished - 9 Aug 2023

Abstract

The positive Ti isotope versus SiO2-content correlation in igneous rocks reflects the fractional crystallization of Ti-bearing oxide minerals. However, Ti isotope variations of subduction-related igneous rocks indicate that the Ti isotope compositions of their mantle sources are heterogeneous and additional mineral phases may promote Ti isotope fractionation. We have determined the Ti isotope composition of well-characterized subduction-related basalts, andesites and boninites. Samples from the Solomon Islands, the Troodos ophiolite in Cyprus, and Cape Vogel in Papua New Guinea show small but resolvable variations that may be related to differences in their mantle sources. Specifically, the δ49Ti of boninites (+0.109‰ to +0.168‰) is slightly higher than that of tholeiites (−0.027‰ to +0.111‰) from the same localities (Troodos in Cyprus and Cape Vogel in Papua New Guinea). Modeling suggests the partial melting of progressively depleted mantle sources where residual Cr-spinel plays a greater role in controlling the Ti budget during partial melting. More pronounced variations in δ49Ti are clearly linked to the fractional crystallization of Ti-oxides: Samples from Rabaul Volcanic Complex (New Britain, Papua New Guinea) show increasing δ49Ti (up to +0.373‰) with increasing Ti/V and decreasing Dy/Yb. Fractional crystallization models suggest that oxide minerals and amphibole are needed to sufficiently increase the δ49Ti of these magmas. Our study highlights that the combination of diagnostic trace element patterns and Ti isotope compositions in subduction-related igneous rocks can be a powerful tool to constrain petrogenetic processes and to discriminate between different crystallizing mineral phases.

Keywords

    stable isotopes, subduction zones, Titanium

ASJC Scopus subject areas

Cite this

Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas. / Kommescher, S.; Kurzweil, F.; Fonseca, R. O.C. et al.
In: Geochemistry, Geophysics, Geosystems, Vol. 24, No. 8, e2022GC010840, 09.08.2023.

Research output: Contribution to journalArticleResearchpeer review

Kommescher, S, Kurzweil, F, Fonseca, ROC, Rzehak, LJA, Hohl, SV, Kirchenbaur, M, Schuth, S, Sprung, P & Münker, C 2023, 'Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas', Geochemistry, Geophysics, Geosystems, vol. 24, no. 8, e2022GC010840. https://doi.org/10.1029/2022GC010840, https://doi.org/10.15488/15366
Kommescher, S., Kurzweil, F., Fonseca, R. O. C., Rzehak, L. J. A., Hohl, S. V., Kirchenbaur, M., Schuth, S., Sprung, P., & Münker, C. (2023). Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas. Geochemistry, Geophysics, Geosystems, 24(8), Article e2022GC010840. https://doi.org/10.1029/2022GC010840, https://doi.org/10.15488/15366
Kommescher S, Kurzweil F, Fonseca ROC, Rzehak LJA, Hohl SV, Kirchenbaur M et al. Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas. Geochemistry, Geophysics, Geosystems. 2023 Aug 9;24(8):e2022GC010840. doi: 10.1029/2022GC010840, 10.15488/15366
Kommescher, S. ; Kurzweil, F. ; Fonseca, R. O.C. et al. / Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas. In: Geochemistry, Geophysics, Geosystems. 2023 ; Vol. 24, No. 8.
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title = "Mineralogical Controls on the Ti Isotope Composition of Subduction Zone Magmas",
abstract = "The positive Ti isotope versus SiO2-content correlation in igneous rocks reflects the fractional crystallization of Ti-bearing oxide minerals. However, Ti isotope variations of subduction-related igneous rocks indicate that the Ti isotope compositions of their mantle sources are heterogeneous and additional mineral phases may promote Ti isotope fractionation. We have determined the Ti isotope composition of well-characterized subduction-related basalts, andesites and boninites. Samples from the Solomon Islands, the Troodos ophiolite in Cyprus, and Cape Vogel in Papua New Guinea show small but resolvable variations that may be related to differences in their mantle sources. Specifically, the δ49Ti of boninites (+0.109‰ to +0.168‰) is slightly higher than that of tholeiites (−0.027‰ to +0.111‰) from the same localities (Troodos in Cyprus and Cape Vogel in Papua New Guinea). Modeling suggests the partial melting of progressively depleted mantle sources where residual Cr-spinel plays a greater role in controlling the Ti budget during partial melting. More pronounced variations in δ49Ti are clearly linked to the fractional crystallization of Ti-oxides: Samples from Rabaul Volcanic Complex (New Britain, Papua New Guinea) show increasing δ49Ti (up to +0.373‰) with increasing Ti/V and decreasing Dy/Yb. Fractional crystallization models suggest that oxide minerals and amphibole are needed to sufficiently increase the δ49Ti of these magmas. Our study highlights that the combination of diagnostic trace element patterns and Ti isotope compositions in subduction-related igneous rocks can be a powerful tool to constrain petrogenetic processes and to discriminate between different crystallizing mineral phases.",
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AU - Kommescher, S.

AU - Kurzweil, F.

AU - Fonseca, R. O.C.

AU - Rzehak, L. J.A.

AU - Hohl, S. V.

AU - Kirchenbaur, M.

AU - Schuth, S.

AU - Sprung, P.

AU - Münker, C.

N1 - Funding Information: The authors thank Bill Leman, Marc‐Alban Millet and one anonymous reviewer who raised several salient points to help improve the manuscript. SK thanks Felix Marxer for discussions and MELTS support, Eric Hasenstab, Christian S. Marien and Liam Hoare for additional discussions that helped shape the manuscript. SK was funded by a UoC Advanced Post Doc grant within the Excellence Initiative to PS, acknowledges the UoC Graduate School of Geosciences for providing a fellowship Grant (GSGS‐2019X‐07) and is now funded by DFG project FO 698/10‐1. The Solomon Islands sampling campaign was funded by the DFG project MU‐1406/2 to CM. FK acknowledges financial support by the German Research Foundation (DFG, Grant KU 3788/1‐1) as part of the priority program 1833 “Building a Habitable Earth”. ROCF is grateful for research funding from the Deutsche Forschungsgemeinschaft (DFG Grant FO 698/14‐1), and the funding of a Heisenberg Professorship by the same entity (Grant FO 698/11‐1).

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N2 - The positive Ti isotope versus SiO2-content correlation in igneous rocks reflects the fractional crystallization of Ti-bearing oxide minerals. However, Ti isotope variations of subduction-related igneous rocks indicate that the Ti isotope compositions of their mantle sources are heterogeneous and additional mineral phases may promote Ti isotope fractionation. We have determined the Ti isotope composition of well-characterized subduction-related basalts, andesites and boninites. Samples from the Solomon Islands, the Troodos ophiolite in Cyprus, and Cape Vogel in Papua New Guinea show small but resolvable variations that may be related to differences in their mantle sources. Specifically, the δ49Ti of boninites (+0.109‰ to +0.168‰) is slightly higher than that of tholeiites (−0.027‰ to +0.111‰) from the same localities (Troodos in Cyprus and Cape Vogel in Papua New Guinea). Modeling suggests the partial melting of progressively depleted mantle sources where residual Cr-spinel plays a greater role in controlling the Ti budget during partial melting. More pronounced variations in δ49Ti are clearly linked to the fractional crystallization of Ti-oxides: Samples from Rabaul Volcanic Complex (New Britain, Papua New Guinea) show increasing δ49Ti (up to +0.373‰) with increasing Ti/V and decreasing Dy/Yb. Fractional crystallization models suggest that oxide minerals and amphibole are needed to sufficiently increase the δ49Ti of these magmas. Our study highlights that the combination of diagnostic trace element patterns and Ti isotope compositions in subduction-related igneous rocks can be a powerful tool to constrain petrogenetic processes and to discriminate between different crystallizing mineral phases.

AB - The positive Ti isotope versus SiO2-content correlation in igneous rocks reflects the fractional crystallization of Ti-bearing oxide minerals. However, Ti isotope variations of subduction-related igneous rocks indicate that the Ti isotope compositions of their mantle sources are heterogeneous and additional mineral phases may promote Ti isotope fractionation. We have determined the Ti isotope composition of well-characterized subduction-related basalts, andesites and boninites. Samples from the Solomon Islands, the Troodos ophiolite in Cyprus, and Cape Vogel in Papua New Guinea show small but resolvable variations that may be related to differences in their mantle sources. Specifically, the δ49Ti of boninites (+0.109‰ to +0.168‰) is slightly higher than that of tholeiites (−0.027‰ to +0.111‰) from the same localities (Troodos in Cyprus and Cape Vogel in Papua New Guinea). Modeling suggests the partial melting of progressively depleted mantle sources where residual Cr-spinel plays a greater role in controlling the Ti budget during partial melting. More pronounced variations in δ49Ti are clearly linked to the fractional crystallization of Ti-oxides: Samples from Rabaul Volcanic Complex (New Britain, Papua New Guinea) show increasing δ49Ti (up to +0.373‰) with increasing Ti/V and decreasing Dy/Yb. Fractional crystallization models suggest that oxide minerals and amphibole are needed to sufficiently increase the δ49Ti of these magmas. Our study highlights that the combination of diagnostic trace element patterns and Ti isotope compositions in subduction-related igneous rocks can be a powerful tool to constrain petrogenetic processes and to discriminate between different crystallizing mineral phases.

KW - stable isotopes

KW - subduction zones

KW - Titanium

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