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Rift-induced disruption of cratonic keels drives kimberlite volcanism

Author

Listed:
  • Thomas M. Gernon

    (University of Southampton)

  • Stephen M. Jones

    (University of Birmingham)

  • Sascha Brune

    (Helmholtz Centre Potsdam – GFZ German Research Centre for Geosciences
    University of Potsdam)

  • Thea K. Hincks

    (University of Southampton)

  • Martin R. Palmer

    (University of Southampton)

  • John C. Schumacher

    (Portland State University)

  • Rebecca M. Primiceri

    (University of Southampton)

  • Matthew Field

    (Mayfield)

  • William L. Griffin

    (Macquarie University)

  • Suzanne Y. O’Reilly

    (Macquarie University)

  • Derek Keir

    (University of Southampton
    Universita degli Studi di Firenze)

  • Christopher J. Spencer

    (Queen’s University)

  • Andrew S. Merdith

    (University of Leeds)

  • Anne Glerum

    (Helmholtz Centre Potsdam – GFZ German Research Centre for Geosciences)

Abstract

Kimberlites are volatile-rich, occasionally diamond-bearing magmas that have erupted explosively at Earth’s surface in the geologic past1–3. These enigmatic magmas, originating from depths exceeding 150 km in Earth’s mantle1, occur in stable cratons and in pulses broadly synchronous with supercontinent cyclicity4. Whether their mobilization is driven by mantle plumes5 or by mechanical weakening of cratonic lithosphere4,6 remains unclear. Here we show that most kimberlites spanning the past billion years erupted about 30 million years (Myr) after continental breakup, suggesting an association with rifting processes. Our dynamical and analytical models show that physically steep lithosphere–asthenosphere boundaries (LABs) formed during rifting generate convective instabilities in the asthenosphere that slowly migrate many hundreds to thousands of kilometres inboard of rift zones. These instabilities endure many tens of millions of years after continental breakup and destabilize the basal tens of kilometres of the cratonic lithosphere, or keel. Displaced keel is replaced by a hot, upwelling mixture of asthenosphere and recycled volatile-rich keel in the return flow, causing decompressional partial melting. Our calculations show that this process can generate small-volume, low-degree, volatile-rich melts, closely matching the characteristics expected of kimberlites1–3. Together, these results provide a quantitative and mechanistic link between kimberlite episodicity and supercontinent cycles through progressive disruption of cratonic keels.

Suggested Citation

  • Thomas M. Gernon & Stephen M. Jones & Sascha Brune & Thea K. Hincks & Martin R. Palmer & John C. Schumacher & Rebecca M. Primiceri & Matthew Field & William L. Griffin & Suzanne Y. O’Reilly & Derek Ke, 2023. "Rift-induced disruption of cratonic keels drives kimberlite volcanism," Nature, Nature, vol. 620(7973), pages 344-350, August.
    • Handle: RePEc:nat:nature:v:620:y:2023:i:7973:d:10.1038_s41586-023-06193-3
    DOI: 10.1038/s41586-023-06193-3
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    Cited by:

    1. Hugo K. H. Olierook & Denis Fougerouse & Luc S. Doucet & Yebo Liu & Murray J. Rayner & Martin Danišík & Daniel J. Condon & Brent I. A. McInnes & A. Lynton Jaques & Noreen J. Evans & Bradley J. McDonal, 2023. "Emplacement of the Argyle diamond deposit into an ancient rift zone triggered by supercontinent breakup," Nature Communications, Nature, vol. 14(1), pages 1-10, December.

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