The Impact of Matrix Rheology on Stress Concentration in Embedded Brittle Clasts

Ioannidi, Paraskevi Io; Bogatz, Kyle; Reber, Jacqueline E.

doi:10.1029/2021gc010127

Cited by 6 publications

(5 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For moderate clast fractions (>0.3), "jamming" of clasts creates load-bearing force chains that amplify clast stresses by 2-14×, depending on clast-matrix strength contrast (Beall et al, 2019a(Beall et al, , 2019bCates et al, 1998;Webber et al, 2018). Even at low clast fractions (<0.1) and in the absence of clast-clast interaction, clast stress shadows, and the matrix itself, can impose stress on clasts resulting in stress amplification of 2-5× that on the matrix (Ioannidi et al, 2022;Ladd & Reber, 2020). These numerical models, experiments and geologic studies are scale independent, and are consistent with the microstructures observed here reflecting stress amplification in strong actinolite due to force-chain formation and/or stress transfer from the weak talc matrix.…”

Section: Strain Rate Variations and Slow Slipmentioning

confidence: 99%

Episodic Slow Slip Hosted by Talc‐Bearing Metasomatic Rocks: High Strain Rates and Stress Amplification in a Chemically Reacting Shear Zone

Hoover

Condit

Lindquist

et al. 2022

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

Section: Strain Rate Variations and Slow Slipmentioning

confidence: 99%

Episodic Slow Slip Hosted by Talc‐Bearing Metasomatic Rocks: High Strain Rates and Stress Amplification in a Chemically Reacting Shear Zone

Hoover

Condit

Lindquist

et al. 2022

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

“…Most garnet porphyroclasts studied previously were metamorphosed under eclogite facies conditions (Yamato et al, 2019;Rogowitz et al, 2023) and hence are embedded in an omphacite-bearing matrix, the rheology of which is much stronger than quartz as for our experiment. A stronger matrix would enable the accumulation of stresses sufficient to produce deformation within the clast under a lower strain rate rather than in the weak matrix (e.g., Beall et al, 2019a;Ioannidi et al, 2022). Yamato et al (2019) found that locally increased stresses at the grain boundaries of garnet crystals can reach their yield strength and cause frictional failure; this deformation might be analogous to our Style 2 deformation.…”

Section: Comparison With Previous Studiesmentioning

confidence: 85%

“…Since in our models we use regular quadratic mesh, elements on the borders of circular garnets contain markers of both materials (inset of Figure 3a). Existence of both types of markers in one element results in the averaging of rheological properties of that element and leads to localization of stresses and subsequently frictional deformation (e.g., Ioannidi et al, 2022).…”

Section: Styles Of Deformationmentioning

confidence: 99%

Garnet fracturing reveals ancient unstable slip events hosted in plate interface metasediments

Angiboust,

Ioannidi,

Muldashev

2023

Preprint

View full text Add to dashboard Cite

A paradox exists between the great number of intermediate-depth earthquakes occurring along active subduction interfaces worldwide and the extreme scarcity of paleo-seismic events recorded in exhumed metasedimentary rocks from ancient subduction zones. Recrystallization, shearing as well as exhumation-related overprinting generally contribute to the nearly-complete erasing of markers of unstable slip events in metamorphic rocks. We herein focus on a sample from an ancient deep thrust from a Cretaceous High-Pressure paleo-accretionary complex in Chilean Patagonia. A representative, moderately foliated micaschist exhibits broken garnet crystals that host a dense network of healed micro-fractures. While garnet fragments appear thoroughly disaggregated along the main foliation, the matrix that has completely recrystallized hardly records brittle deformation. We employ a 2D visco-elasto-plastic numerical modelling approach in order to investigate the mechanical conditions that enable the fracturing of isolated garnet grains in a relatively weak matrix. The rupture of these stiff grains is achieved in our models at strain rates faster than 10-10 /s to 10-12 /s for elevated pore fluid pressures (80 to 99% of the lithostatic value, respectively). Since high pore fluid pressures prevail in deep subduction interface settings, it is suggested that the rupture of these garnet crystals occurred through cataclastic deformation via (transient) slip rate acceleration, perhaps as a consequence of localized slip associated with slow to normal earthquakes. Upon slip rate deceleration, viscous disaggregation of the broken garnet clasts occurred along with the erasing of the matrix cataclastic fabric.

show abstract

“…For moderate clast fractions (>0.3), "jamming" of clasts creates load-bearing force chains that amplify clast stresses by 2-14x, depending on clast-matrix strength contrast (Beall et al, 2019a;2019b;Cates et al, 1998;Webber et al, 2018). Even at low clast fractions (<0.1) and in the absence of clast-clast interaction, clast stress shadows, and the matrix itself, can impose stress on clasts resulting in stress amplification of 2-5x that on the matrix (Ioannidi et al, 2022;Ladd & Reber, 2020). These numerical models, experiments and geologic studies are scale independent, and are consistent with the microstructures observed here reflecting stress amplification in strong actinolite due to force-chain formation and/or stress transfer from the weak talc matrix.…”

Section: Strain Rate Variations and Slow Slipmentioning

confidence: 99%

Episodic slow slip hosted by talc-bearing metasomatic rocks: High strain rates and stress amplification in a chemically reacting shear zone

Hoover

Condit

Lindquist

et al. 2022

Preprint

View full text Add to dashboard Cite

Episodic tremor and slow slip (ETS) downdip of the subduction seismogenic zone are poorly understood slip behaviors of the seismic cycle. Talc, a common metasomatic mineral at the subduction interface, is suggested to host slow slip but this hypothesis has not been tested in the rock record. We investigate actinolite microstructures from talc-bearing and talc-free rocks exhumed from the depths of modern ETS (Pimu'nga/Santa Catalina Island, California). Actinolite deformed by dissolutionreprecipitation creep in the talc-free rock and dislocation creep ± cataclasis in the talc-bearing rock. This contrast results from stress amplification in the talc-bearing rock produced by high strain rates in surrounding weak talc. We hypothesize that higher strain rates in the talc-bearing sample represent episodic slow slip, while lower strain rates in the talc-free sample represent intervening aseismic creep. This work highlights the need to consider fluid-mediated chemical change in studies of subduction zone deformation and seismicity.

show abstract

The Impact of Matrix Rheology on Stress Concentration in Embedded Brittle Clasts

Cited by 6 publications

References 62 publications

Episodic Slow Slip Hosted by Talc‐Bearing Metasomatic Rocks: High Strain Rates and Stress Amplification in a Chemically Reacting Shear Zone

Episodic Slow Slip Hosted by Talc‐Bearing Metasomatic Rocks: High Strain Rates and Stress Amplification in a Chemically Reacting Shear Zone

Garnet fracturing reveals ancient unstable slip events hosted in plate interface metasediments

Episodic slow slip hosted by talc-bearing metasomatic rocks: High strain rates and stress amplification in a chemically reacting shear zone

Contact Info

Product

Resources

About