Earthquakes generated in subduction zones are caused by unstable movements along faults. This fault-slip instability is determined by frictional forces that depend on the temperature, pressure, morphology and deformation state of the fault rocks. Fault friction may also be influenced by preferred mineral orientations. Over-thrusting of rocks at the interface between a subducting slab and the overlying mantle wedge generates shear deformation that causes minerals to align, and this preferred mineral orientation affects the propagation of shear seismic waves. Here we use laboratory experiments to simulate fault slip in antigorite, the most abundant hydrous mineral phase within Earth's upper mantle. Using atomic force microscopy, we show that antigorite single crystals possess strong frictional anisotropy on their basal slip surface and that preferred mineral alignment extends this property to a regional scale. Depending on the alignment, fault movements can occur along a high-friction direction, creating stick-slip behaviour that generates earthquakes. In contrast, if movements occur along a low-friction direction, the mantle wedge will deform aseismically. Our results imply that mantle rocks in subduction-zone thrust faults can exhibit two opposite frictional behaviours, seismic and aseismic. © 2013 Macmillan Publishers Limited.

Campione, M., Capitani, G. (2013). Subduction-zone earthquake complexity related to frictional anisotropy in antigorite. NATURE GEOSCIENCE, 6(10), 847-851 [10.1038/ngeo1905].

Subduction-zone earthquake complexity related to frictional anisotropy in antigorite

CAMPIONE, MARCELLO
;
CAPITANI, GIANCARLO
2013

Abstract

Earthquakes generated in subduction zones are caused by unstable movements along faults. This fault-slip instability is determined by frictional forces that depend on the temperature, pressure, morphology and deformation state of the fault rocks. Fault friction may also be influenced by preferred mineral orientations. Over-thrusting of rocks at the interface between a subducting slab and the overlying mantle wedge generates shear deformation that causes minerals to align, and this preferred mineral orientation affects the propagation of shear seismic waves. Here we use laboratory experiments to simulate fault slip in antigorite, the most abundant hydrous mineral phase within Earth's upper mantle. Using atomic force microscopy, we show that antigorite single crystals possess strong frictional anisotropy on their basal slip surface and that preferred mineral alignment extends this property to a regional scale. Depending on the alignment, fault movements can occur along a high-friction direction, creating stick-slip behaviour that generates earthquakes. In contrast, if movements occur along a low-friction direction, the mantle wedge will deform aseismically. Our results imply that mantle rocks in subduction-zone thrust faults can exhibit two opposite frictional behaviours, seismic and aseismic. © 2013 Macmillan Publishers Limited.
Articolo in rivista - Articolo scientifico
Subduction zone; serpentine; slab-mantle interface; nanotribology; anisotropic friction;
English
2013
6
10
847
851
none
Campione, M., Capitani, G. (2013). Subduction-zone earthquake complexity related to frictional anisotropy in antigorite. NATURE GEOSCIENCE, 6(10), 847-851 [10.1038/ngeo1905].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/46766
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