Evidence for deep mantle convection and primordial heterogeneity from nitrogen and carbon stable isotopes in diamond

Diamond, as the deepest sample available for study, provides a unique opportunity to sample and examine parts of the Earth’s mantle not directly accessible. In order to provide further constraints on mantle convection and deep volatile cycles, we analysed nitrogen and carbon isotopes and nitrogen ab...

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Bibliographic Details
Published in:Earth and planetary science letters 2012-12, Vol.357-358, p.179-193
Main Authors: Palot, M., Cartigny, P., Harris, J.W., Kaminsky, F.V., Stachel, T.
Format: Article
Language:English
Subjects:
Brazil
Carbon
Convection
diamonds
Heterogeneity
Homogeneity
Inclusions
Mantle
mantle convection
mantle volatiles
primordial heterogeneity
Sciences of the Universe
Signatures
stable isotopes
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Summary:Diamond, as the deepest sample available for study, provides a unique opportunity to sample and examine parts of the Earth’s mantle not directly accessible. In order to provide further constraints on mantle convection and deep volatile cycles, we analysed nitrogen and carbon isotopes and nitrogen abundances in 133 diamonds from Juina (Brazil) and Kankan (Guinea). Host syngenetic inclusions within these diamonds indicate origins from the lithosphere, the asthenosphere-transition zone and the lower mantle. Juina and Kankan diamonds both display overall carbon isotopic compositions within the current upper mantle range but the δ13C signatures of diamonds from the asthenosphere-transition zone extend toward very negative and positive values, respectively. Two Kankan diamonds with both lower mantle and asthenosphere-transition zone inclusions (KK-45 and KK-83) are zoned in δ13C, and have signatures consistent with multiple growth steps likely within both the lower mantle and the asthenosphere-transition zone illustrating the transfer of material through the 670km seismic discontinuity. At a given locality, diamonds from the upper and the lower mantle show similar δ15N distributions with coinciding modes within the range defined by typical upper mantle samples, as one might expect for a well stirred reservoir resulting from whole mantle convection. Kankan diamonds KK-11 (lower mantle), KK-21 and KK-92 (both lithospheric) display the lowest δ15N values (-24.9%, -39.4% and -30.4%) ever measured in terrestrial samples, which we interpret as reflecting primordial heterogeneity preserved in an imperfectly mixed convective mantle. Our diamond data thus provide support for deeply rooted convection cells, together with the preservation of primordial volatiles in an imperfectly mixed convecting mantle, thereby reconciling the conflicting interpretations regarding mantle homogeneity derived from geochemical and geophysical studies. ► Diamonds illustrate large material transfer across the 670km seismic discontinuity. ► Kankan diamonds record the contribution of primordial nitrogen with δ15N
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2012.09.015