Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean)

A. Pietranik; C. Storey; J. Koepke; S. Lasalle

doi:10.1007/s00410-016-1324-y

Details

Original language	English
Article number	10
Journal	Contributions to Mineralogy and Petrology
Volume	172
Issue number	2-3
Early online date	14 Feb 2017
Publication status	Published - Mar 2017

Abstract

Felsic veins (plagiogranites) are distributed throughout the whole oceanic crust section and offer insight into late-magmatic/high temperature hydrothermal processes within the oceanic crust. Despite constituting only 0.5% of the oceanic crust section drilled in IODP Site 735B, they carry a significant budget of incompatible elements, which they redistribute within the crust. Such melts are saturated in accessory minerals, such as zircon, titanite and apatite, and often zircon is the only remaining phase that preserves magmatic composition and records processes of felsic melt formation and evolution. In this study, we analysed zircon from four depths in IODP Site 735B; they come from the oxide gabbro (depth approximately 250 m below sea floor) and plagiogranite (depths c. 500, 860, 940 m below sea floor). All zircons have similar εHf composition of c. 15 units indicating an isotopically homogenous source for the mafic magmas forming IODP Site 735B gabbro. Zircons from oxide gabbro are scarce and variable in composition consistent with their crystallization from melts formed by both fractionation of mafic magmas and hydrous remelting of gabbro cumulate. On the other hand, zircon from plagiogranite is abundant and each sample is characterized by compositional trends consistent with crystallization of zircon in an evolving melt. However, the trends are different between the plagiogranite at 500 m bsf and the deeper sections, which are interpreted as the record of plagiogranite formation by two processes: remelting of gabbro cumulate at 500 m bsf and fractionation at deeper sections. Zircon from both oxide gabbro and plagiogranite has δ¹⁸O from 3.5 to 6.0‰. Values of δ¹⁸O are best explained by redistribution of δ¹⁸O in a thermal gradient and not by remelting of hydrothermally altered crust. Tentatively, it is suggested that fractionation could be an older episode contemporaneous with gabbro crystallization and remelting could be a younger one, triggered by deformation and uplift of the crustal pile.

Keywords

Felsic melt, Fractionation, Hf, O isotopes, Hydrous melting, Oceanic crust, Trace elements, Zircon crystallization

ASJC Scopus subject areas

Earth and Planetary Sciences(all)
Geophysics
Earth and Planetary Sciences(all)
Geochemistry and Petrology

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Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean). / Pietranik, A.; Storey, C.; Koepke, J. et al.
In: Contributions to Mineralogy and Petrology, Vol. 172, No. 2-3, 10, 03.2017.

Research output: Contribution to journal › Article › Research › peer review

Pietranik, A, Storey, C, Koepke, J & Lasalle, S 2017, 'Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean)', Contributions to Mineralogy and Petrology, vol. 172, no. 2-3, 10. https://doi.org/10.1007/s00410-016-1324-y

Pietranik, A., Storey, C., Koepke, J., & Lasalle, S. (2017). Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean). Contributions to Mineralogy and Petrology, 172(2-3), Article 10. https://doi.org/10.1007/s00410-016-1324-y

Pietranik A, Storey C, Koepke J, Lasalle S. Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean). Contributions to Mineralogy and Petrology. 2017 Mar;172(2-3):10. Epub 2017 Feb 14. doi: 10.1007/s00410-016-1324-y

Pietranik, A. ; Storey, C. ; Koepke, J. et al. / Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean). In: Contributions to Mineralogy and Petrology. 2017 ; Vol. 172, No. 2-3.

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abstract = "Felsic veins (plagiogranites) are distributed throughout the whole oceanic crust section and offer insight into late-magmatic/high temperature hydrothermal processes within the oceanic crust. Despite constituting only 0.5% of the oceanic crust section drilled in IODP Site 735B, they carry a significant budget of incompatible elements, which they redistribute within the crust. Such melts are saturated in accessory minerals, such as zircon, titanite and apatite, and often zircon is the only remaining phase that preserves magmatic composition and records processes of felsic melt formation and evolution. In this study, we analysed zircon from four depths in IODP Site 735B; they come from the oxide gabbro (depth approximately 250 m below sea floor) and plagiogranite (depths c. 500, 860, 940 m below sea floor). All zircons have similar εHf composition of c. 15 units indicating an isotopically homogenous source for the mafic magmas forming IODP Site 735B gabbro. Zircons from oxide gabbro are scarce and variable in composition consistent with their crystallization from melts formed by both fractionation of mafic magmas and hydrous remelting of gabbro cumulate. On the other hand, zircon from plagiogranite is abundant and each sample is characterized by compositional trends consistent with crystallization of zircon in an evolving melt. However, the trends are different between the plagiogranite at 500 m bsf and the deeper sections, which are interpreted as the record of plagiogranite formation by two processes: remelting of gabbro cumulate at 500 m bsf and fractionation at deeper sections. Zircon from both oxide gabbro and plagiogranite has δ18O from 3.5 to 6.0‰. Values of δ18O are best explained by redistribution of δ18O in a thermal gradient and not by remelting of hydrothermally altered crust. Tentatively, it is suggested that fractionation could be an older episode contemporaneous with gabbro crystallization and remelting could be a younger one, triggered by deformation and uplift of the crustal pile.",

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AU - Storey, C.

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AU - Lasalle, S.

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Research@Leibniz University

Zircon record of fractionation, hydrous partial melting and thermal gradients at different depths in oceanic crust (ODP Site 735B, South-West Indian Ocean)

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