The Stability Transition From Stable to Unstable Frictional Slip With Finite Pore Pressure

Affinito, R.; Wood, C.; Marty, S.; Elsworth, D.; Marone, C.

doi:10.1029/2023gl105568

Geophysical Research Letters

2023

DOI: 10.1029/2023gl105568

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The Stability Transition From Stable to Unstable Frictional Slip With Finite Pore Pressure

R. Affinito,

C. Wood,

S. Marty

et al.

Abstract: Pore fluids are ubiquitous throughout the lithosphere and are commonly invoked as the cause of induced seismicity and slow earthquakes. We perform lab experiments to address these questions for drained fault conditions and low pore pressure. We shear simulated faults at effective normal stress of 20 MPa and pore pressures Pp from 1 to 4 MPa. We document the full range of lab earthquake behaviors from slow slip to elasto‐dynamic rupture and show that slow slip can be explained by the slip rate dependence of th… Show more

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2024

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A laboratory perspective on accelerating preparatory processes before earthquakes and implications for foreshock detectability

Goebel,

Schuster,

Kwiatek

et al. 2024

Nat Commun

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Dynamic failure in the laboratory is commonly preceded by many foreshocks which accompany premonitory aseismic slip. Aseismic slip is also thought to govern earthquake nucleation in nature, yet, foreshocks are rare. Here, we examine how heterogeneity due to different roughness, damage and pore pressures affects premonitory slip and acoustic emission characteristics. High fluid pressures increase stiffness and reduce heterogeneity which promotes more rapid slip acceleration and shorter precursory periods, similar to the effect of low geometric heterogeneity on smooth faults. The associated acoustic emission activity in low-heterogeneity samples becomes increasingly dominated by earthquake-like double-couple focal mechanisms. The similarity of fluid pressure increase and roughness reduction suggests that increased stress and geometric homogeneity may substantially shorten the duration of foreshock activity. Gradual fault activation and extended foreshock activity is more likely observable on immature faults at shallow depth.

show abstract

A laboratory perspective on accelerating preparatory processes before earthquakes and implications for foreshock detectability

Goebel,

Schuster,

Kwiatek

et al. 2024

Nat Commun

View full text Add to dashboard Cite

show abstract

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The Stability Transition From Stable to Unstable Frictional Slip With Finite Pore Pressure

Cited by 1 publication

References 53 publications

A laboratory perspective on accelerating preparatory processes before earthquakes and implications for foreshock detectability

A laboratory perspective on accelerating preparatory processes before earthquakes and implications for foreshock detectability

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