Shear strain concentration mechanism in the lower crust below an intraplate strike-slip fault based on rheological laws of rocks

Zhang, Xuelei; Sagiya, Takeshi

doi:10.1186/s40623-017-0668-5

Cited by 16 publications

(18 citation statements)

References 42 publications

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“…Results indicate that a combination of deformation in the upper crust as well as ductile deformation in the lower crust may contribute to the high strain rate in the northeastern NKTZ. Zhang and Sagiya (2017) modeled strain concentration in two dimensions within the lower crust, assuming steady fault sliding in the upper crust and ductile flow in the lower crust according to laboratoryderived power-law rheology with a yield threshold at the brittle-ductile transition. Possible physical mechanisms for strain concentration in the lower crust are investigated including frictional and shear heating, grain size, and power-law creep, taking account also of the role of water in promoting crystal plasticity.…”

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confidence: 99%

Crustal dynamics: unified understanding of geodynamic processes at different time and length scales

Iio

Sibson

Takeshita

et al. 2018

Earth Planets Space

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confidence: 99%

Crustal dynamics: unified understanding of geodynamic processes at different time and length scales

Iio

Sibson

Takeshita

et al. 2018

Earth Planets Space

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“…Water fugacity is calculated with the van der Waals equation (Karato, 2012). The detailed calculation method can be found in Zhang and Sagiya (2017).…”

Section: Rheologiesmentioning

confidence: 99%

“…Previous investigations of the deformation of the lower crust and the upper mantle using mechanical models have shown that localized shear deformation can be developed in the lower crust under the interplate (e.g., Allison & Dunham, 2018;Moore & Parsons, 2015;Takeuchi & Fialko, 2012;Thatcher & England, 1998) and intraplate (e.g., Zhang & Sagiya, 2017) strike-slip faults. Some of these models considered earthquake cycles (e.g., Allison & Dunham, 2018;Erickson et al, 2017;Lambert & Barbot, 2016;Takeuchi & Fialko, 2012) and others considered a creeping fault (e.g., Moore & Parsons, 2015;Thatcher & England, 1998;Zhang & Sagiya, 2017) in the upper crust. The localized deformation in the lower crust under a fault appears in all these models.…”

Section: Comparison With Mechanical Models For Interplate Strike-slipmentioning

confidence: 99%

“…Our simulation demonstrates that this spin-up corresponds to the tectonic stress buildup, and the fault behavior can be highly variable during this period. Without careful examination of the initial settings, unrealistic behavior appears, such as the negative shear strain rate (Takeuchi & Fialko, 2012) or extremely large shear stress right below the upper crust (e.g., Moore & Parsons, 2015;Zhang & Sagiya, 2017). Inappropriate model assumptions may have led to those unexpected results.…”

Section: Comparison With Mechanical Models For Interplate Strike-slipmentioning

confidence: 99%

“…Various observations indicate shear localization occurs even under a very low slip rate condition of intraplate faults. Zhang and Sagiya () investigated physical mechanism of shear zone formation under a slow slip rate condition and concluded that the power law rheology plays the principal role; however, the formation of shear zone was not modeled in that study. As the stress propagates in the material with nonlinear (power law) rheology (Melosh, ), it is important to understand the evolution of shear stress and strain distribution in the crust.…”

Section: Introductionmentioning

confidence: 99%

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Intraplate Strike‐Slip Faulting, Stress Accumulation, and Shear Localization of a Crust‐Upper Mantle System With Nonlinear Viscoelastic Material

Zhang

Sagiya

2018

JGR Solid Earth

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We investigate the evolution of tectonic background stress and elastic as well as inelastic strain in a crust‐upper mantle system around an infinitely long vertical strike‐slip fault in a self‐consistent mechanical earthquake cycle model. In the early stage of the stress evolution, deformation of the crust and the upper mantle is dominated by a uniform simple shear. Shear localization in the lower crust starts when coseismic rupture extends to the entire brittle upper crust. Together with this transition, the earthquake recurrence intervals decrease by an order of magnitude due to a basal drag originated from a localized plastic flow of the lower crust. After the shear zone is fully developed in the lower crust, the fault slip rate catches up with the far‐field velocity and earthquakes starts to occur periodically. Such a steady state can be reached in several hundred thousand years from the beginning, which includes few hundreds of earthquake cycles. A shear zone with large cumulative strain needs a few million years to develop under an intraplate strike‐slip fault, which is much longer than the time for shear strain rate to be localized. The model successfully reproduced evolution of tectonic stress around an intraplate strike‐slip fault, interacting with the development of localized shear zone in the lower crust. The model demonstrates the importance of considering the whole mechanical system in which rheological structure and fault activities interacting with each other for the better understanding of the intraplate earthquakes.

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Numerical investigation for the fractional nonlinear space‐time telegraph equation via the trigonometric Quintic B‐spline scheme

Khater

Nisar

Mohamed

2020

Math Methods in App Sciences

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This manuscript employs the trigonometric Quintic B‐spline (TQBS) scheme for investigating the numerical solution of the conformable fractional nonlinear time‐space telegraph equation. This model is derived by Oliver Heaviside 1880 to describe the cutting‐edge or voltage of an electrified transmission range with the day yet distance from an electrified transmission or electromagnetic wave's application. In Hamed and Khater, three recent computational schemes (sech–tanh expansion method; extended sinh–Gorden expansion method; and extended simplest equation method) have been applied to the fractional model for constructing the exact traveling wave solutions. Many distinct solutions have been obtained, and some of them have been sketched in two, three‐dimensional, and density plots. Here, these solutions are investigated to evaluate the initial and boundary conditions that apply the suggested numerical scheme. The accuracy of the constructed exact solutions is investigated by calculating the absolute value of error. The most accurate numerical schemes of the three applied computational schemes have been illustrated.

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Shear strain concentration mechanism in the lower crust below an intraplate strike-slip fault based on rheological laws of rocks

Cited by 16 publications

References 42 publications

Crustal dynamics: unified understanding of geodynamic processes at different time and length scales

Crustal dynamics: unified understanding of geodynamic processes at different time and length scales

Intraplate Strike‐Slip Faulting, Stress Accumulation, and Shear Localization of a Crust‐Upper Mantle System With Nonlinear Viscoelastic Material

Numerical investigation for the fractional nonlinear space‐time telegraph equation via the trigonometric Quintic B‐spline scheme

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