TY - GEN
T1 - Stress Distribution in Accreting Sediments
T2 - 58th US Rock Mechanics / Geomechanics Symposium 2024, ARMA 2024
AU - Lopez-Campos, G.
AU - Nikolinakou, M. A.
AU - Flemings, P. B.
AU - Saffer, D. M.
N1 - Publisher Copyright:
Copyright 2024 ARMA, American Rock Mechanics Association.
PY - 2024
Y1 - 2024
N2 - 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.
AB - 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.
UR - http://www.scopus.com/inward/record.url?scp=85213041586&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85213041586&partnerID=8YFLogxK
U2 - 10.56952/ARMA-2024-0708
DO - 10.56952/ARMA-2024-0708
M3 - Conference contribution
AN - SCOPUS:85213041586
T3 - 58th US Rock Mechanics / Geomechanics Symposium 2024, ARMA 2024
BT - 58th US Rock Mechanics / Geomechanics Symposium 2024, ARMA 2024
PB - American Rock Mechanics Association (ARMA)
Y2 - 23 June 2024 through 26 June 2024
ER -