Premium
Microstructural evidence for seismic and aseismic slips along clay‐bearing, carbonate faults
Author(s) -
Smeraglia Luca,
Bettucci Andrea,
Billi Andrea,
Carminati Eugenio,
Cavallo Andrea,
Di Toro Giulio,
Natali Marco,
Passeri Daniele,
Rossi Marco,
Spagnuolo Elena
Publication year - 2017
Publication title -
journal of geophysical research: solid earth
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.983
H-Index - 232
eISSN - 2169-9356
pISSN - 2169-9313
DOI - 10.1002/2017jb014042
Subject(s) - geology , slip (aerodynamics) , carbonate , clastic rock , fault gouge , creep , shear (geology) , calcite , fault (geology) , geotechnical engineering , seismology , mineralogy , petrology , sedimentary rock , composite material , materials science , geochemistry , physics , metallurgy , thermodynamics
In this multimethodological study, microstructural observations of fault rocks are combined with micromechanical property analyses (contact resonance atomic force microscopy (CR‐AFM)) and with rotary friction experiments (Slow‐ to High‐Velocity rotary‐shear friction Apparatus apparatus) to find evidence of seismic to aseismic slip and understand the nanoscale rheology of clay‐bearing, carbonate‐hosted faults. Fluidized structures, truncated clasts, pores and vesicles, and phyllosilicate nanosized spherules and tubes suggest fast deformation events occurred during seismic slip, whereas clay‐assisted pressure‐solution processes, clumped clasts, foliation surfaces, and mantled clasts indicate slow deformation events occurred during postseismic/interseismic periods. CR‐AFM measurements show that the occurrence of ~5 wt % of clay within the carbonate‐hosted gouges can significantly reduce the fault core stiffness at nanoscale. In addition, during high‐velocity friction experiments simulating seismic slip conditions, the presence of ultrathin phyllosilicate‐bearing (≤3 wt %) layers within calcite gouges, as those observed in the natural fault, show faster dynamic weakening than that of pure calcite gouges. The weak behavior of such layers could facilitate the upward propagation of seismic slip during earthquakes, thus possibly enhancing surface faulting. Microstructural observations and experimental evidence fit some well‐known geophysical and geodetic observations on the short‐ to long‐term mechanical behavior of faults such as postseismic/interseismic aseismic creep, interseismic fault locking, and seismic slip propagation up to the Earth's surface.