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Deep intra-slab rupture and mechanism transition of the 2024 Mw 7.4 Calama earthquake

Author

Listed:
  • Zhe Jia

    (UT Austin)

  • Wei Mao

    (University of Chinese Academy of Sciences
    California Institute of Technology)

  • María Constanza Flores

    (Universidad de Chile
    Universidad de Chile)

  • Sebastián Barra

    (Universidad de Chile)

  • Sergio Ruiz

    (Universidad de Chile)

  • Bertrand Potin

    (Universidad de Chile)

  • Thorsten W. Becker

    (UT Austin
    UT Austin
    UT Austin)

  • Marcos Moreno

    (Pontificia Universidad Católica de Chile)

  • Juan Carlos Baez

    (Universidad de Chile)

  • Daniel Ceroni

    (Universidad de Chile)

  • Leoncio Cabrera

    (Pontificia Universidad Católica de Chile)

Abstract

While subduction zone hazard is dominated by the megathrust, intermediate-depth (70–300 km) earthquakes within the slab can likewise have catastrophic impacts. Their physics remains enigmatic, with suggested mechanisms including dehydration embrittlement and thermal runaway. Here, we investigate the 2024 Chile, Mw 7.4 intermediate-depth earthquake and compare the rupture extent with temperature conditions from thermo-mechanical models. We record regional geodetic co-seismic deformation and high-resolution seismicity associated with this type of event. Our analyses reveal a complex rupture spanning an exceptional depth range, with distinct asperities propagating deep into the subducting lithosphere. Comparison with thermal models shows that while the rupture initiated within the cold slab core, it extended well beyond the ~650 °C isotherm that typically delineates the boundary for efficient serpentine dehydration. We suggest that the rupture likely initiated with dehydration embrittlement within the cold core but then propagated into the warmer regions through shear thermal runaway. This implies a transition of mechanisms that facilitates large-scale rupture and activates typically aseismic, high-temperature slab regions. Our findings highlight the importance of considering interactions between rupture mechanisms as well as slab thermal and compositional settings to better understand the processes governing intermediate-depth earthquakes.

Suggested Citation

  • Zhe Jia & Wei Mao & María Constanza Flores & Sebastián Barra & Sergio Ruiz & Bertrand Potin & Thorsten W. Becker & Marcos Moreno & Juan Carlos Baez & Daniel Ceroni & Leoncio Cabrera, 2025. "Deep intra-slab rupture and mechanism transition of the 2024 Mw 7.4 Calama earthquake," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-63480-5
    DOI: 10.1038/s41467-025-63480-5
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    References listed on IDEAS

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    1. Jiaxuan Li & Taeho Kim & Nadia Lapusta & Ettore Biondi & Zhongwen Zhan, 2023. "The break of earthquake asperities imaged by distributed acoustic sensing," Nature, Nature, vol. 620(7975), pages 800-806, August.
    2. Peter B. Kelemen & Greg Hirth, 2007. "A periodic shear-heating mechanism for intermediate-depth earthquakes in the mantle," Nature, Nature, vol. 446(7137), pages 787-790, April.
    3. Thomas P. Ferrand & Nadège Hilairet & Sarah Incel & Damien Deldicque & Loïc Labrousse & Julien Gasc & Joerg Renner & Yanbin Wang & Harry W. Green II & Alexandre Schubnel, 2017. "Dehydration-driven stress transfer triggers intermediate-depth earthquakes," Nature Communications, Nature, vol. 8(1), pages 1-11, August.
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