Ridge-push force and the state of stress in the Nubia-Somalia plate system

Mahatsente, R.; Coblentz, David

doi:10.1130/l441.1

Cited by 14 publications

(13 citation statements)

References 62 publications

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“…In the EARS the magnitude of deviatoric stress is in a range of 10–20 MPa (Mahatsente & Coblentz, 2015; Stamps et al., 2010), and hence, it appears to be too small to cause brittle failure on seismogenic faults (Craig et al., 2011; Scholz, 2002). Mahatsente and Coblentz (2015) argue that the ridge‐push force from the oceanic part of Nubia (Africa)‐Somalia plate is less than the integrated strength of the African plate and hence additional forces are required to deform the plate. The above studies report magnitude of vertically averaged deviatoric stress over the thickness of the lithosphere.…”

Section: Comparison and Discussion Of Resultsmentioning

confidence: 99%

Mechanism for Deep Crustal Seismicity: Insight From Modeling of Deformation Processes at the Main Ethiopian Rift

Muluneh

Brune

Illsley‐Kemp

et al. 2020

Geochem Geophys Geosyst

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We combine numerical modeling of lithospheric extension with analysis of seismic moment release and earthquake b‐value in order to elucidate the mechanism for deep crustal seismicity and seismic swarms in the Main Ethiopian Rift (MER). We run 2‐D numerical simulations of lithospheric deformation calibrated by appropriate rheology and extensional history of the MER to simulate migration of deformation from mid‐Miocene border faults to ∼30 km wide zone of Pliocene to recent rift floor faults. While currently the highest strain rate is localized in a narrow zone within the rift axis, brittle strain has been accumulated in a wide region of the rift. The magnitude of deviatoric stress shows strong variation with depth. The uppermost crust deforms with maximum stress of 80 MPa, at 8–14 km depth stress sharply decreases to 10 MPa and then increases to a maximum of 160 MPa at ∼18 km depth. These two peaks at which the crust deforms with maximum stress of 80 MPa or above correspond to peaks in the seismic moment release. Correspondingly, the drop in stress at 8–14 km correlates to a low in seismic moment release. At this depth range, the crust is weaker and deformation is mainly accommodated in a ductile manner. We therefore see a good correlation between depths at which the crust is strong and elevated seismic deformation, while regions where the crust is weaker deform more aseismically. Overall, the bimodal depth distribution of seismic moment release is best explained by the rheology of the deforming crust.

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Section: Comparison and Discussion Of Resultsmentioning

confidence: 99%

Mechanism for Deep Crustal Seismicity: Insight From Modeling of Deformation Processes at the Main Ethiopian Rift

Muluneh

Brune

Illsley‐Kemp

et al. 2020

Geochem Geophys Geosyst

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“…Heidbach et al, 2007) and deformation patterns (Gerbault, 2000;Cloetingh et al, 2005). Furthermore, it is common that forces are calculated using the integral of the horizontal deviatoric stresses (Ghosh et al, 2006;Mahatsente and Coblentz, 2015) that are lower by a factor of two (see Schmalholz et al, 2019) than the differential stress usually used to calculate lithosphere forces.…”

Section: Driving and Resisting Factorsmentioning

confidence: 99%

“…Although the above quoted modelling studies successfully simulate the initiation of subduction zones at passive margins upon vertical or horizontal loading, the stress levels required for the nucleation of subduction are usually significantly higher than plate tectonic forces (England and Wortel, 1980;Cloetingh et al, 1989;Mueller and Phillips, 1991;Gerbault, 2000;Gurnis et al, 2004;Zhong and Li, 2019). In fact, the stress needed for subduction initiation at passive margins is in general one order of magnitude larger than the horizontal component of stress generated by ridge push (Mahatsente and Coblentz, 2015). From a mechanical perspective, it is important to note that the critical stress for subduction initiation is also higher by ∼5 TN than the lithospheric yield strength at (slow spreading) mid-ocean ridges (Luttrell and Sandwell, 2012).…”

Section: Introductionmentioning

confidence: 99%

Kinematic Boundary Conditions Favouring Subduction Initiation at Passive Margins Over Subduction at Mid-oceanic Ridges

2021

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We perform numerical modelling to simulate the shortening of an oceanic basin and the adjacent continental margins in order to discuss the relationship between compressional stresses acting on the lithosphere and the time dependent strength of the mid-oceanic ridges within the frame of subduction initiation. We focus on the role of stress regulating mechanisms by testing the stress–strain-rate response to convergence rate, and the thermo-tectonic age of oceanic and continental lithospheres. We find that, upon compression, subduction initiation at passive margin is favoured for thermally thin (Palaeozoic or younger) continental lithospheres (<160 km) over cratons (>180 km), and for oceanic basins younger than 60 Myr (after rifting). The results also highlight the importance of convergence rate that controls stress distribution and magnitudes in the oceanic lithosphere. Slow convergence (<0.9 cm/yr) favours strengthening of the ridge and build-up of stress at the ocean-continent transition allowing for subduction initiation at passive margins over subduction at mid-oceanic ridges. The results allow for identifying geodynamic processes that fit conditions for subduction nucleation at passive margins, which is relevant for the unique case of the Alps. We speculate that the slow Africa–Europe convergence between 130 and 85 Ma contributes to the strengthening of the mid-oceanic ridge, leading to subduction initiation at passive margin 60–70 Myr after rifting and passive margin formation.

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“…Forsyth, 1973;Turcotte & Schubert, 2014). Although the contribution of each mechanism is unclear (Swedan, 2015), ridge push represents integrated deviatoric stress values between 1 and 5 TN/m (Mahatsente & Coblentz, 2015;Mueller & Phillips, 1991;Swedan, 2015), with an average value in the order of 3.5 TN/m for a 75 Myr oceanic lithosphere (Mahatsente, 2017). However, in some places, stress arising from the oceanic plate are of equal magnitude as the GPE from thick continental lithosphere (e.g.…”

Section: Stress Magnitudes In Oceanic Basinsmentioning

confidence: 99%

“…Although the above quoted modelling studies successfully simulate the initiation of subduction zones at passive margins upon vertical or horizontal loading, the stress levels required for the nucleation of subduction are usually significantly higher than plate tectonic forces (Cloetingh et al, 1989;England & Wortel, 1980;Gerbault, 2000;Gurnis et al, 2004;Mueller & Phillips, 1991;Zhong & Li, 2019). In fact, the stress needed for subduction initiation at passive margins is in general one order of magnitude larger than the horizontal component of stress generated by ridge push (Mahatsente & Coblentz, 2015). From a mechanical perspective, it is important to note that the critical stress for subduction initiation is also higher by ~5 TN than the lithospheric yield strength at (slow spreading) mid-ocean ridges (Luttrell & Sandwell, 2012).…”

Section: Introductionmentioning

confidence: 99%

Rheological and kinematic conditions for forced subduction initiation at continental passive margins

Auzemery¹

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Antoine Auzemery -Rheological and kinematic conditions for forced subduction initiation at continental passive margins 1 Rheological and kinematic conditions for forced subduction initiation at continental passive margins Reologische en kinematische vereisten voor initiatie van geforceerde subductie op continentale passieve marges (met een samenvatting in het Nederlands) Conditions rhéologiques et cinématiques pour l'initiation de la subduction forcée aux marges passives continentales (avec un résumé en français) Proefschrift ter verkrijging van de graad van doctor aan de Universiteit Utrecht op gezag van de rector magnificus, prof.dr. H.R.B.M. Kummeling, ingevolge het besluit van het college voor promoties in het openbaar te verdedigen op vrijdag 3 september 2021 des middags te 2.

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Ridge-push force and the state of stress in the Nubia-Somalia plate system

Cited by 14 publications

References 62 publications

Mechanism for Deep Crustal Seismicity: Insight From Modeling of Deformation Processes at the Main Ethiopian Rift

Mechanism for Deep Crustal Seismicity: Insight From Modeling of Deformation Processes at the Main Ethiopian Rift

Kinematic Boundary Conditions Favouring Subduction Initiation at Passive Margins Over Subduction at Mid-oceanic Ridges

Rheological and kinematic conditions for forced subduction initiation at continental passive margins

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