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1. Impact of Spontaneous Generation of Splay Faults on Stress Heterogeneity in Accreting Sediments

   https://doi.org/10.56952/ARMA-2025-0338  

   Lopez-Campos, G; Nikolinakou, MA; Flemings, PB; Saffer, DM (June 2025, ARMA)

   ABSTRACT:We model the progressive generation and propagation of faults in accreting sediments and study how this process affects stress and deformation in the accretionary wedge. We develop large-scale evolutionary drained geomechanical models. We simulate sediment behavior using a porous elasto-plastic constitutive formulation that incorporates the effect of both mean and shear stress to compaction. We integrate a FEM-DEM framework that enables faulting when the deviatoric plastic strain exceeds a specified threshold over a specified length. New faults are introduced to the mesh as contact surfaces with a friction angle lower than that of the intact sediment. We find that the weaker faults lead to a decrease in sediment differential stress in zones that extend several hundred meters away from the fault. This introduces a significant heterogeneity in both stress and strength within the accretionary wedge. The heterogeneity propagates seaward as the wedge evolves and new faults are generated. We also explore the effect of fault frictional strength through parametric analyses. We find that weaker faults result in more extensive areas of low differential stress and delay the generation of the next set of faults at the toe of the wedge. Our results offer a significant improvement over previous models of continuum wedge sediments that predict Coulomb failure throughout the wedge. Our study provides insights into the state of stress in faulted accretionary wedges, highlighting the spatial heterogeneity of stress and its potential impact on factors influencing seismic cycles in subduction zones. 

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2. Stress Distribution in Accreting Sediments: A Geomechanical Study of Upper-Plate Faults

   https://doi.org/10.56952/ARMA-2024-0708  

   Lopez-Campos, G; Nikolinakou, M A; Flemings, P B; Saffer, D M (June 2024, ARMA)

   ABSTRACT:We study the influence of an upper-plate fault on the stress state of accreting sediments under large-scale deformation. We develop drained evolutionary geomechanical models using the Finite Element program Elfen. We simulate sediments as porous-elastoplastic material, and we model the fault as a pre-existing contact surface with a varying frictional strength that is lower than the intact sediment. The weaker fault results in a decrease in sediment differential stress near and especially seaward of the fault. A significant section of the wedge is affected by this stress variation. In contrast, the stress ratio is that of Coulomb failure further away from the fault. We also show that the maximum principal stress the sediments can support decreases with decreasing fault strength. This study offers a significant improvement over previous models of continuum wedge sediments that predict Coulomb failure throughout the wedge. Our results improve our understanding of near-fault stress state, hence improving our understanding of seismic hazards in subduction zones and providing practical insights for reservoir quality and the design of safe and economic well trajectories. 1 INTRODUCTIONAccretionary wedges are geological structures that develop at convergent plate boundaries, particularly at subduction zones. They form as a result of offscraping sediments from the subducting oceanic plate, which then accumulates on the leading edge of the overriding plate (e.g., Moore et al., 2011; Buiter et al., 2016; Gao et al., 2018).Understanding the state of stress in accretionary wedges is crucial for the study of earthquake mechanics in subduction zones (e.g., Brodsky et al., 2017; Huffman and Saffer, 2016; Suppe, 2007). It provides insights for earthquake occurrence, large or slow-slip events (e.g., Kodaira et al., 2012; Tobin et al., 2022; Liu and Rice, 2007) and tsunami potential (e.g., Dean et al., 2010; Riedel et al., 2016). In addition, estimates of mean and differential stress, as well as porosity evolution can help improve the assessment of reservoir quality and the design of safe and economic well trajectories (e.g., Morley et al., 2011).The accumulation of sediments in an accretionary wedge resembles a bulldozer gathering snow as it moves. Hence, wedge sediments are often assumed to be at compressional failure (e.g., Davis et al., 1983; Dahlen et al., 1984; Flemings and Saffer, 2018). Several field observations of faulting, folding and lateral compression as seen in seismic images and drilling measurements (e.g., Flemings and Saffer, 2018; Henry et al., 2003; Moore et al., 1990; Westbrook et al., 1988) provide evidence that the accretionary wedge is at a state of failure in compression. 

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3. Path and Slip Dependent Behavior of Shallow Subduction Shear Zones During Fluid Overpressure

   https://doi.org/10.1029/2023JB027502  

   Belzer, Benjamin D.; French, Melodie E. (April 2024, Journal of Geophysical Research: Solid Earth)

   Abstract Elevated pore fluid pressure is proposed to contribute to slow earthquakes along shallow subduction plate boundaries. However, the processes that create high fluid pressure, disequilibrium compaction and dehydration reactions, lead to different effective stress paths in fault rocks. These paths are predicted by granular mechanics frameworks to lead to different strengths and deformation modes, yet granular mechanics do not predict their effects on fault stability. To evaluate the role of fluid overpressure on shallow megathrust strength and slip behavior, we conducted triaxial shear experiments on chlorite and celadonite rich gouge layers. Experiments were conducted at constant temperature (130 and 100°C), confining pressure (130 and 140 MPa), and pore fluid pressures (between 10 and 120 MPa). Fluid overpressure due to disequilibrium compaction was simulated by increasing confining and pore fluid pressure synchronously without exceeding the target effective pressure, whereas overpressure due to dehydration reactions was simulated by first loading the sample to a target isotropic effective pressure and then increasing pore fluid pressure to reduce the effective pressure. We find that the effects of fluid pressure and stress path on the mechanical behavior of the chlorite and celadonite gouges can generally be described using the critical state soil mechanics (CSSM) framework. However, path effects are more pronounced and persist to greater displacements in chlorite because its microstructure is more influenced by stress path. Due to its effects on microstructure, the stress path also imparts greater control on the rate‐dependence of chlorite strength, which is not predicted by CSSM. 

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4. Late Quaternary Surface Displacements on Accretionary Wedge Splay Faults in the Cascadia Subduction Zone: Implications for Megathrust Rupture

   https://doi.org/10.26443/seismica.v2i4.1158  

   Ledeczi, Anna; Lucas, Madeleine; Tobin, Harold; Watt, Janet; Miller, Nathan (April 2024, Seismica)

   Because splay faults branch at a steep dip angle from the plate-boundary décollement in an accretionary wedge, their coseismic displacement can potentially result in larger tsunamis with distinct characteristics compared to megathrust-only fault ruptures, posing an enhanced hazard to coastal communities. Elsewhere, there is evidence of coseismic slip on splay faults during many of the largest subduction zone earthquakes, but our understanding of potentially active splay faults and their hazards at the Cascadia subduction zone remains limited. To identify the most recently active splay faults at Cascadia, we conduct stratigraphic and structural interpretations of near-surface deformation in the outer accretionary wedge for the ~400 km along-strike length of the landward vergence zone. We analyze recently acquired high-frequency sparker seismic data and crustal-scale multi-channel seismic data to examine the record of deformation in shallow slope basins and the upper ~1 km of the surrounding accreted sediments and to investigate linkages to deeper décollement structure. We present a new fault map for widest, most completely locked portion of Cascadia from 45 to 48°N latitude, which documents the distribution of faults that show clear evidence of recent late Quaternary activity. We find widespread evidence for active splay faulting up to 30 km landward of the deformation front, in what we define as the active domain, and diminished fault activity landward outside of this zone. The abundance of surface-deforming splay faults in the active outer wedge domain suggests Cascadia megathrust events may commonly host distributed shallow rupture on multiple splay faults located within 30 km of the deformation front. 

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5. Along-strike variations in protothrust zone characteristics at the Nankai Trough subduction margin

   https://doi.org/10.1130/GES02305.1  

   Tilley, Hannah L.; Moore, Gregory F.; Yamashita, Mikiya; Kodaira, Shuichi (February 2021, Geosphere)

   null (Ed.)

   Abstract Significant along-strike changes in the protothrust zone at the toe of the Nankai Trough accretionary prism were imaged in new high-resolution seismic reflection data. The width of the protothrust zone varies greatly along strike; two spatially discrete segments have a wide protothrust zone (∼3.3–7.8 km, ∼50–110 protothrusts), and two segments have almost no protothrust zone (∼0.5–2.8 km, <20 protothrusts). The widest protothrust zone occurs in the region with the widest and thickest sediment wedge and subducting turbidite package, both of which are influenced by basement topography. The trench wedge size and lithology, the lithology of the subducting section, and the basement topography all influence the rate of consolidation in the trench wedge, which we hypothesize is an important control over the presence and width of the protothrust zone. We conclude that protothrusts are fractures that form from shear surfaces in deformation band clusters as the trench fill sediment is consolidated. Strain localization occurs at sites with a high density of protothrusts, which become the probable locations of future frontal thrust propagation. The frontal thrust may propagate forward with a lower buildup of strain where it is adjacent to a wide protothrust zone than at areas with a narrow or no protothrust zone. This is reflected in the accretionary prism geometry, where wide protothrust zones occur adjacent to fault-propagation folds with shallow prism toe surface slopes. 

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