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Metamorphism and the evolution of plate tectonics

Author

Listed:
  • Robert M. Holder

    (Johns Hopkins University
    University of Michigan)

  • Daniel R. Viete

    (Johns Hopkins University)

  • Michael Brown

    (University of Maryland)

  • Tim E. Johnson

    (Curtin University
    China University of Geosciences)

Abstract

Earth’s mantle convection, which facilitates planetary heat loss, is manifested at the surface as present-day plate tectonics1. When plate tectonics emerged and how it has evolved through time are two of the most fundamental and challenging questions in Earth science1–4. Metamorphic rocks—rocks that have experienced solid-state mineral transformations due to changes in pressure (P) and temperature (T)—record periods of burial, heating, exhumation and cooling that reflect the tectonic environments in which they formed5,6. Changes in the global distribution of metamorphic (P, T) conditions in the continental crust through time might therefore reflect the secular evolution of Earth’s tectonic processes. On modern Earth, convergent plate margins are characterized by metamorphic rocks that show a bimodal distribution of apparent thermal gradients (temperature change with depth; parameterized here as metamorphic T/P) in the form of paired metamorphic belts5, which is attributed to metamorphism near (low T/P) and away from (high T/P) subduction zones5,6. Here we show that Earth’s modern plate tectonic regime has developed gradually with secular cooling of the mantle since the Neoarchaean era, 2.5 billion years ago. We evaluate the emergence of bimodal metamorphism (as a proxy for secular change in plate tectonics) using a statistical evaluation of the distributions of metamorphic T/P through time. We find that the distribution of metamorphic T/P has gradually become wider and more distinctly bimodal from the Neoarchaean era to the present day, and the average metamorphic T/P has decreased since the Palaeoproterozoic era. Our results contrast with studies that inferred an abrupt transition in tectonic style in the Neoproterozoic era (about 0.7 billion years ago1,7,8) or that suggested that modern plate tectonics has operated since the Palaeoproterozoic era (about two billion years ago9–12) at the latest.

Suggested Citation

  • Robert M. Holder & Daniel R. Viete & Michael Brown & Tim E. Johnson, 2019. "Metamorphism and the evolution of plate tectonics," Nature, Nature, vol. 572(7769), pages 378-381, August.
  • Handle: RePEc:nat:nature:v:572:y:2019:i:7769:d:10.1038_s41586-019-1462-2
    DOI: 10.1038/s41586-019-1462-2
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    Cited by:

    1. Cindy Luisier & Lucie Tajčmanová & Philippe Yamato & Thibault Duretz, 2023. "Garnet microstructures suggest ultra-fast decompression of ultrahigh-pressure rocks," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Polina Lemenkova, 2022. "Handling Dataset with Geophysical and Geological Variables on the Bolivian Andes by the GMT Scripts," Data, MDPI, vol. 7(6), pages 1-18, June.
    3. Zibra Ivan & Kemp Anthony I S & Smithies R Hugh & Rubatto Daniela & Korhonen Fawna & Hammerli Johannes & Johnson Tim E & Gessner Klaus & Weinberg Roberto F & Vervoort Jeff D & Martin Laure & Romano Sa, 2022. "Greenstone burial–exhumation cycles at the late Archean transition to plate tectonics," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    4. Bo Huang & Man Liu & Timothy M. Kusky & Tim E. Johnson & Simon A. Wilde & Dong Fu & Hao Deng & Qunye Qian, 2023. "Changes in orogenic style and surface environment recorded in Paleoproterozoic foreland successions," Nature Communications, Nature, vol. 14(1), pages 1-14, December.

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