Production of nanoparticles during experimental deformation of smectite and implications for seismic slip

Aretusini, Stefano; Mittempergher, Silvia; Plümper, Oliver; Spagnuolo, Elena; Gualtieri, Alessandro F.; Toro, Giulio Di

doi:10.1016/j.epsl.2017.01.048

Cited by 33 publications

(55 citation statements)

References 44 publications

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“…1a), quartz peaks appear in the Raman transect in the center ∼50% of the diameter, and in the outer rim of wear material, the powder is more evenly distributed. This observation of increased wear and amorphization at higher slip speeds is similar to previous experiments on clay-quartz mixtures 19 .…”

Section: Resultssupporting

confidence: 91%

Earthquake lubrication and healing explained by amorphous nanosilica

et al. 2019

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During earthquake propagation, geologic faults lose their strength, then strengthen as slip slows and stops. Many slip-weakening mechanisms are active in the upper-mid crust, but healing is not always well-explained. Here we show that the distinct structure and rate-dependent properties of amorphous nanopowder (not silica gel) formed by grinding of quartz can cause extreme strength loss at high slip rates. We propose a weakening and related strengthening mechanism that may act throughout the quartz-bearing continental crust. The action of two slip rate-dependent mechanisms offers a plausible explanation for the observed weakening: thermally-enhanced plasticity, and particulate flow aided by hydrodynamic lubrication. Rapid cooling of the particles causes rapid strengthening, and inter-particle bonds form at longer timescales. The timescales of these two processes correspond to the timescales of post-seismic healing observed in earthquakes. In natural faults, this nanopowder crystallizes to quartz over 10s–100s years, leaving veins which may be indistinguishable from common quartz veins.

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Section: Resultssupporting

confidence: 91%

Earthquake lubrication and healing explained by amorphous nanosilica

et al. 2019

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“…an aseismic regime) at slow slip-rates to velocity weakening (i.e. seismic) at high slip-rate (Faulkner et al, 2011;Aretusini et al, 2017). (Faulkner et al, 2011) have postulated that this switch is due to thermal pressurization of pore fluid in the clay.…”

Section: Implication In Terms Of Triggered "Ultra-shallow" (< 2 Km) Smentioning

confidence: 99%

An Alternative View of the Microseismicity along the Western Main Marmara Fault

Batsi

Lomax²,

Tary

et al. 2018

Bulletin of the Seismological Society of America

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A detailed study, based on ocean-bottom seismometers (OBSs) recordings from two recording periods (3.5 months in 2011 and 2 months in 2014) and on a high-resolution, 3D velocity model, is presented here, which provides an alternative view of the microseismicity along the submerged section of the North Anatolian fault (NAF) within the western Sea of Marmara (SoM). The nonlinear probabilistic software packages of NonLinLoc and NLDiffLoc were used for locating earthquakes. Only earthquakes that comply with the following location criteria (e.g., representing 20% of the total amount of events) were considered for analysis: (1) number of stations≥5; (2) number of phases≥6, including both P and S; (3) root mean square (rms) location error≤0.5 s; and (4) azimuthal gap≤180°. P and S travel times suggest that there are strong velocity anomalies along the Western High, with low Vp, low Vs, and ultrahigh Vp/Vs in areas where mud volcanoes and gas-prone sediment layers are known to be present. The location results indicate that not all earthquakes occurred as strike-slip events at crustal depths (>8 km) along the axis of the Main Marmara fault (MMF). In contrast, the following features were observed: (1) a significant number of earthquakes occurred off-axis (e.g., 24%), with predominantly normal focal mechanisms, at depths between 2 and 6 km, along tectonically active, structural trends oriented eastwest or southwest-northeast, and (2) a great number of earthquakes was also found to occur within the upper sediment layers (at depths<2 km), particularly in the areas where free gas is suspected to exist, based on high-resolution 3D seismics (e.g., 28%). Part of this ultra-shallow seismicity appears to occur Please note that this is an author-produced PDF of an article accepted for publication following peer review. The definitive publisher-authenticated version is available on the publisher Web site. in response to deep earthquakes of intermediate (ML∼4-5) magnitude. Resolving the depth of the shallow seismicity requires adequate experimental design ensuring source-receiver distances of the same order as hypocentral depths. To reach this objective, deep-seafloor observatories with a sufficient number of geophone sensors near the fault trace are needed.

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“…However, recent results from laboratory experiments on clays at high slip-rates (i.e. >2 m/s) 50,51 have shown that clays can react seismically to rupture that propagates into it, one such example being the 2011 Tohoku earthquake where 30 m of slip is estimated to have occurred in clay like material 52 . A similar scenario could apply to explain the ultra-shallow events that occurred at depths of less than a few hundred meters.…”

Section: Introductionmentioning

confidence: 99%

Gas and seismicity within the Istanbul seismic gap

Géli

Henry

Grall

et al. 2018

Sci Rep

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Understanding micro-seismicity is a critical question for earthquake hazard assessment. Since the devastating earthquakes of Izmit and Duzce in 1999, the seismicity along the submerged section of North Anatolian Fault within the Sea of Marmara (comprising the “Istanbul seismic gap”) has been extensively studied in order to infer its mechanical behaviour (creeping vs locked). So far, the seismicity has been interpreted only in terms of being tectonic-driven, although the Main Marmara Fault (MMF) is known to strike across multiple hydrocarbon gas sources. Here, we show that a large number of the aftershocks that followed the M 5.1 earthquake of July, 25th 2011 in the western Sea of Marmara, occurred within a zone of gas overpressuring in the 1.5–5 km depth range, from where pressurized gas is expected to migrate along the MMF, up to the surface sediment layers. Hence, gas-related processes should also be considered for a complete interpretation of the micro-seismicity (~M < 3) within the Istanbul offshore domain.

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Production of nanoparticles during experimental deformation of smectite and implications for seismic slip

Cited by 33 publications

References 44 publications

Earthquake lubrication and healing explained by amorphous nanosilica

Earthquake lubrication and healing explained by amorphous nanosilica

An Alternative View of the Microseismicity along the Western Main Marmara Fault

Gas and seismicity within the Istanbul seismic gap

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