Ranero, C. R., Phipps Morgan, J. & Reichert, C. Bending-related faulting and mantle serpentinization on the Center America Trench. Nature 425, 367–373 (2003).
Ranero, C. R. & Sallarès, V. Geophysical proof for hydration of the crust and mantle of the Nazca Plate throughout bending on the North Chile Trench. Geology 32, 549–552 (2004).
Grevemeyer, I., Ranero, C. R., Flueh, E. R., Kläschen, D. & Bialas, J. Passive and lively seismological research of bending-related faulting and mantle serpentinization on the Center America Trench. Earth Planet. Sci. Lett. 258, 528–542 (2007).
Faccenda, M., Gerya, T. V. & Burlini, L. Deep slab hydration induced by bending associated variations in tectonic strain. Nat. Geosci. 2, 790–793 (2009).
Van Avendonk, H. J. A., Holbrook, W. S., Lizarralde, D. & Denyer, P. Construction and serpentinization of the subducting Cocos Plate offshore Nicaragua and Costa Rica. Geochem. Geophys. Geosyst.12, Q06009 (2011).
Nakamura, Y., Kodaira, S., Miura, S., Regalla, C., Takahashi, N. Excessive-resolution seismic imaging within the Japan Trench axis space off Miyagi, northeastern Japan. Geophys. Res. Lett. 40, 1713–1718 (2013).
Boston, B., Moore, G. F., Nakamura, Y. & Kodaira, S. Outer-rise regular fault improvement and affect on near-trench décollement propagation alongside the Japan Trench, off Tohoku. Earth Planets House 66, 135 (2014).
Shillington, D. J. et al. Hyperlink between plate material, hydration and subduction zone seismicity in Alaska. Nat. Geosci. 8, 961–964 (2015).
Korenaga, J. On the extent of mantle hydration attributable to plate bending. Earth Plant. Sci. Lett. 457, 1–9 (2017).
Petersen, R. I., Stegman, D. R. & Tackley, P. J. The subduction dichotomy of robust plates and weak slabs. Strong Earth. https://doi.org/10.5194/se-2016-56 (2016).
Tao, Okay., Grand, S. P. &Niu, F. Seismic construction of the higher mantle beneath jap Asia from full waveform seismic tomography. Geochem. Geophys. Geosyst. 19, 2732–2763 (2018).
Kawakatsu, H. et al. Seismic proof for sharp lithosphere–asthenosphere boundaries of oceanic plates. Science 324, 499–502 (2009).
Wang, X. et al. Distinct slab interfaces imaged inside the mantle transition zone. Nat. Geosci. 13, 822–827 (2020).
Freed, A. M. et al. Resolving depth-dependent subduction zone viscosity and afterslip from postseismic displacements following the 2011 Tohoku-oki, Japan earthquake. Earth Planet. Sci. Lett. 459, 279–290 (2017).
Herzberg, C. et al. Thermal historical past of the Earth and its petrological expression. Earth Planet. Sci. Lett. 292, 79–88 (2010).
van Hunen, J. & van den Berg, A. Plate tectonics on the early Earth: limitations imposed by power and buoyancy of subducted lithosphere. Lithos 103, 217–235 (2008).
Sizova, E., Gerya, T., Brown, M. & Perchuk, L. L. Subduction kinds within the Precambrian: perception from numerical experiments. Lithos 116, 209–229 (2010).
Zhong, S. & Davies, G. F. Results of plate and slab viscosities on the geoid. Earth Plant. Sci. Lett. 170, 487–496 (1999).
Billen, M. I. & Gurnis, M. Constraints on subducting plate power inside the Kermadec Trench. J. Geophys. Res. 110, B05407 (2005).
van Summeren, J., Conrad, C. P. & Lithgow-Bertelloni, C. The significance of slab pull and a world asthenosphere to plate motions. Geochem. Geophys. Geosyst. 13, Q0AK03 (2012).
Garel, F. et al. Interplay of subducted slabs with the mantle transition‐zone: a regime diagram from 2‐D thermo‐mechanical fashions with a cellular trench and an overriding plate. Geochem. Geophys. Geosyst. 15, 1739–1765 (2014).
Tao, W. C. & O’Connell, R. J. Deformation of a weak subducted slab and variation of seismicity with depth. Nature 361, 626–628 (1993).
Wu, B., Conrad, C. P., Heuret, A., Lithgow-Bertelloni, C. & Lallemand,S. Reconciling robust slab pull and weak plate bending: the plate movement constraint on the power of mantle slabs. Earth Planet. Sci. Lett. 272, 412–421 (2008).
Gerya, T. V., Connolly, J. A. D. & Yuen, D. A. Why is terrestrial subduction one-sided? Geology 36, 43–46 (2008).
Čížková, H., van Hunen, J., van den Berg, A. P. & Vlaar, N. J. The affect of rheological weakening and yield stress on the interplay of slabs with the 670-km discontinuity. Earth Planet. Sci. Lett. 199, 447–457 (2002).
Ribe, N. M. Bending mechanics and mode choice in free subduction: a thin-sheet evaluation. Geophys. J. Int. 180, 559–576 (2010).
Ghosh, A., Becker, T. W. & Zhong, S. J. Results of lateral viscosity variations on the geoid. Geophys. Res. Lett. 37, L01301 (2010).
Ranalli, G. Rheology of the Earth (Chapman and Corridor, 1995).
Funiciello, F. et al. Trench migration, web rotation and slab–mantle coupling. Earth Planet. Sci. Lett. 271, 233–240.
Liu, L. & Stegman, D. R. Segmentation of the Farallon slab. Earth Planet. Sci. Lett. 311, 1–10 (2011).
Craig, T. J., Copley, A. & Jackson, J. A reassessment of outer-rise seismicity and its implications for the mechanics of oceanic lithosphere. Geophys. J. Int. 197, 63–89 (2014).
Bercovici, D., Ricard, Y. Mechanisms for the era of plate tectonics by two- part grain-damage and pinning. Phys. Earth Planet. Inter. 202–203, 27–55 (2012).
Mulyukova, E. & Bercovici, D. Formation of lithospheric shear zones: impact of temperature on two-phase grain injury. Phys. Earth Planet. Inter. 270, 195–212 (2017).
Mulyukova, E. & Bercovici, D. Collapse of passive margins by lithospheric injury and plunging grain measurement. Earth. Planet. Sci. Lett. 484, 341–352 (2018).
Mulyukova, E. & Bercovici, D. The era of of plate tectonics from grains to international scales: a short overview. Tectonics 38, 4058–4076 (2019).
Bercovici, D. & Mulyukova, E. Evolution and demise of passive margins by means of grain mixing and injury. Proc. Natl Acad. Sci. USA 118, e2011247118 (2021).
Gurnis, M., Corridor, C. & Lavier, L., Evolving drive stability throughout incipient subduction. Geochem. Geophys. Geosyst. 5, Q07001 (2004).
Masson, D. G. Fault patterns at outer trench partitions. Mar. Geophys. Res. 13, 209–225 (1991).
Ranero, C. R., Villasenor, A., Morgan, J. P. & Weinrebe, W. Relationship between bend-faulting at trenches and intermediate-depth seismicity. Geochem. Geophys. Geosyst. 6, Q12002 (2005).
Lavier, L. L., Buck, W. R. & Poliakov, A. N. B. Elements controlling regular fault offset in a perfect brittle layer. J. Geophys. Res. 105, 23431–23442 (2000).
Choi, E., Lavier, L. & Gurnis, M. Thermomechanics of mid-ocean ridge segmentation. Phys. Earth Planet. Inter. 171, 374–386 (2008).
Whitney, D. L., Teyssier, C., Rey, P. & Buck, W. R. Continental and oceanic core complexes. Geol. Soc. Am. Bull. 125, 273–298 (2013).
Hirauchi, Okay., Fukushima, Okay., Kido, M., Muto, J. & Okamoto, A. Response-induced rheological weakening allows oceanic plate subduction. Nat. Commun. 7, 12550 (2016).
Duretz, T. et al. The significance of structural softening for the evolution and structure of passive margins. Sci. Rep. 6, 38704 (2016).
John,T. et al. Technology of intermediate-depth earthquakes by self-localizing thermal runaway. Nat. Geosci. 2, 137–140 (2009).
Pozzi, G. et al. Coseismic ultramylonites: an investigation of nanoscale viscous circulation and fault weakening throughout seismic slip. Earth Planet. Sci. Lett. 516, 164–175 (2019).
Verberne, B. A. et al. Microscale cavitation as a mechanism for nucleating earthquakes on the base of the seismogenic zone. Nat. Commun. 8, 1645 (2017).
Craig, T. J., Copley, A. & Middleton, T. A. Constraining fault friction in oceanic lithosphere utilizing the dip angles. Earth Planet. Sci. Lett. 392, 94–99 (2014).
Brace, W. F. & Kohlstedt, D. T. Limits on lithospheric stress imposed by laboratory experiments. J. Geophys. Res. 85, 6248–6252 (1980).
Boston, B., Moore, G. F., Nakamura,Y. & Kodaira, S. Forearc slope deformation above the Japan Trench megathrust: implications for subduction erosion. Earth Planet. Sci. Lett. 462, 26–34 (2017).
Boneh, Y. et al. Intermediate-depth earthquakes managed by incoming plate hydration alongside bending-related faults. Geophys. Res. Lett. 46, 3688–3697 (2019).
Naliboff, J. B., Billen, M. I., Gerya, T. & Saunders, J. Dynamics of outer rise faulting in oceanic–continental subduction techniques. Geochem. Geophys. Geosyst.14, 2310–2327 (2013).
Faul, U. H. & Jackson, I. The seismological signature of temperature and grain measurement variations within the higher mantle. Earth Planet. Sci. Lett. 234, 119–134 (2005).
Honda, S. Energy of slab inferred from the seismic tomography and geologic historical past across the Japanese Islands. Geochem. Geophys. Geosyst. 15, 1333–1347 (2014).
Turner, A. J., Katz, R. F. & Behn, M. D. Grain-size dynamics beneath mid-ocean ridges: Implications for permeability and soften extraction. Geochem. Geophys. Geosyst.16, 925–946 (2015).
Gerya, T. V. & Yuen, D. A., Traits-based marker-in-cell technique with conservative finite-differences schemes for modeling geological flows with strongly variable transport properties. Phys. Earth Planet. Inter. 140, 293–318 (2003).
Gerya T. V. Introduction to Numerical Geodynamic Modelling 2nd edn (Cambridge Univ. Press, 2019).
Karato, S. & Wu, P. Rheology of the higher mantle: a synthesis. Science 260, 771–778 (1993).
Hofmeister, A. M. Mantle values of thermal conductivity and the geotherm from phonon lifetimes. Science 283, 1699–1706 (1999).
Turcotte, D. L. & Schubert, G. Geodynamics (Cambridge Univ. Press, 2002).
Clauser, C. & Huenges, E. in Rock Physics and Section Relations AGU Reference Shelf 3 (ed. Ahrens, T. J.) 105–126 (American Geophysical Union, 1995).
Hirth, G. & Kohlstedt, D. in Subduction Issue Monograph Vol. 138 (ed. Eiler, J.) 83–105 (American Geophysical Union, 2003).
Hilairet, N. B. et al. Excessive‐strain creep of serpentine, interseismic deformation, and initiation of subduction. Science 318, 1910–1913 (2007).
Schmeling, H. et al. A benchmark comparability of spontaneous subduction fashions: In the direction of a free floor. Phys. Earth Planet. Inter. 171, 198–223 (2008).
Gerya, T. V. & Yuen, D. A. Rayleigh–Taylor instabilities from hydration and melting propel “chilly plumes” at subduction zones. Earth Planet. Sci. Lett. 212, 47–62 (2003).
Baitsch-Ghirardello, B., Gerya, T. V. & Burg, J.-P. Geodynamic regimes of intra-oceanic subduction: implications forearc extension vs. shortening processes. Gondwana Res. 25, 546–560 (2014).
Katsura, T. & Ito, E. The system Mg2SiO4–Fe2SiO4 at excessive pressures and temperatures: exact willpower of stabilities of olivine, modified spinel, and spinel. J. Geophys. Res. 94, 663–670 (1989).
Ito, E. et al. Detrimental strain–temperature slopes for reactions forming MgSiO3 perovskite from calorimetry. Science 2J9, 1275–1278 (1990).
Ito, Okay. & Kennedy, G. C. in The Construction and Bodily Properties of the Earth’s Crust Geophysical Monograph Collection 14 (ed. Heacock, J. G.) 303–314 (American Geophysical Union, 1971).
Bercovici, D. & Ricard, Y. Technology of plate tectonics with two-phase grain-damage and pinning: supply–sink mannequin and toroidal circulation. Earth Planet. Sci. Lett. 365, 275–288 (2013).
Bercovici, D. & Ricard, Y. Plate tectonics, injury and inheritance. Nature 508, 513–516 (2014).
Bercovici, D., Schubert, G. & Ricard, Y. Abrupt tectonics and fast slab detachment with grain injury. Proc. Natl Acad. Sci. USA 112, 1287–1291 (2015).
Rozel, A., Ricard, Y. & Bercovici, D. A thermodynamically self-consistent injury equation for grain measurement evolution throughout dynamic recrystallization. Geophys. J. Int. 184, 719–728 (2011).
Hayes, P. et al. Slab2, a complete subduction zone geometry mannequin. Science 362, 58–61 (2018).
Hen, P. An up to date digital mannequin of plate boundaries. Geochem. Geophys. Geosyst. 4, 1027 (2003).