How fault evolution changes strain partitioning and fault slip rates in Southern California: Results from geodynamic modeling

Ye, Jiyang; Liu, Mian

doi:10.1002/2017jb014325

Cited by 20 publications

(8 citation statements)

References 87 publications

(176 reference statements)

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“…The shear zone connects to the Walker Lane belt and exists due to the strain imposed by rifting in the Gulf of California on the south and motion of the Sierra Nevada microplate away from the extending Basin and Range in the north, as well as due to the mechanical anisotropy of the lithosphere associated with Miocene Basin and Range extension (Li & Liu, 2006; M. Liu et al., 2010; Plattner et al., 2010). The inability of the misaligned southern SAF (i.e., “big bend”) to accommodate plate motion results in the ECSZ as well as other regional structures, including the Transverse Ranges and San Jacinto fault (Dixon & Xie, 2018; Dokka et al., 1998; Thatcher et al., 2016; Ye & Liu, 2017).…”

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

“…This zone can be divided into several domains of distinct deformation style that have accommodated a total of ∼50–75 km of dextral slip over the past ∼6–10 Ma (Andrew & Walker, 2016; Dokka & Travis, 1990a, 1990b; Glazner et al., 2002; Jachens et al., 2002; Lease et al., 2009; Singleton & Gans, 2008). Although activity is thought to have been diachronous and evolved with changes in regional strain partitioning (e.g., onset of the San Jacinto fault at 1–2 Ma), the timing of onset of individual faults and overall spatiotemporal evolution of the ECSZ are not well constrained (Andrew & Walker, 2016; Glazner et al., 2002; M. Liu et al., 2010; D. M. Miller & Yount, 2002; M. M. Miller et al., 2001; Oskin & Iriondo, 2004; Oskin et al., 2007; Ye & Liu, 2017).…”

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

“…Liu et al, 2010;Plattner et al, 2010). The inability of the misaligned southern SAF (i.e., "big bend") to accommodate plate motion results in the ECSZ as well as other regional structures, including the Transverse Ranges and San Jacinto fault (Dixon & Xie, 2018;Dokka et al, 1998;Thatcher et al, 2016;Ye & Liu, 2017).…”

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

“…Liu et al, 2010;D. M. Miller & Yount, 2002; M. M. Miller et al, 2001;Oskin & Iriondo, 2004;Oskin et al, 2007;Ye & Liu, 2017).…”

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

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Kinematics and Evolution of the Southern Eastern California Shear Zone, Based on Analysis of Fault Strike, Distribution, Activity, Roughness, and Secondary Deformation

Spotila

Garvue

2021

Tectonics

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The Eastern California shear zone (ECSZ) is a major element of the Pacific-North America plate boundary that has been extensively studied, yet displays unexplained kinematic traits. The shear zone is wide and consists of discontinuous, irregular strike-slip faults, rather than a well-integrated fault zone. Individual faults in the ESCZ are more closely spaced and geometrically complex than other comparable secondary zones of strike-slip, such as to the west of the southern San Andreas fault (SAF), to the east of the SAF in northern California, and in the Marlborough fault system of New Zealand. The geometric complexity of faults in the ECSZ also results in complex stepovers and strain transfer zones, which impact rupture pattern and strain partitioning in unknown ways. Kinematic models of the spatiotemporal evolution and rotation of the ECSZ exist, yet these have not been thoroughly tested (Dixon & Xie, 2018;Dokka & Travis, 1990a, 1990bNur et al., 1993). There is thus need for systematic study of the kinematics of faulting in the ECSZ.The ECSZ is also an ideal setting to investigate the influence of geometry on fault processes. The geometry and kinematics of faults and fault networks are relevant for both our understanding of their mechanical behavior and for seismic hazards. Geometric complexity on faults is a form of roughness, which can influence rupture dimension and style, fault strength and stress field, slip distribution and heterogeneity during rupture, and earthquake recurrence (

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Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

“…Liu et al, 2010;D. M. Miller & Yount, 2002; M. M. Miller et al, 2001;Oskin & Iriondo, 2004;Oskin et al, 2007;Ye & Liu, 2017).…”

Section: Tectonic Background Of the Ecszmentioning

confidence: 99%

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Kinematics and Evolution of the Southern Eastern California Shear Zone, Based on Analysis of Fault Strike, Distribution, Activity, Roughness, and Secondary Deformation

Spotila

Garvue

2021

Tectonics

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“…Although the Polochic Fault is contemporarily considered a minor fault of the plate boundary (Authemayou et al, 2012;Franco et al, 2012), it still bears the risk of producing recurring M W 6-7 earthquakes (Brocard, Anselmetti, & Teyssier, 2016). This is, to some degree, analogous to the strike-slip system of the Eastern California Shear Zone, where strain is transferred north from the San Andreas Fault (Ye & Liu, 2017), and where the majority of recent, large earthquakes have localized (Fialko, Simons, & Agnew, 2001;Haukksson, Jones, Hutton, & Eberhart-Phillips, 1993;Ross et al, 2019). indicating that the Polochic Fault was the only fault of the plate boundary between 15 and 10 Ma (Scenario 1) or between 12 and 7 Ma (Scenario 4).…”

Section: Tectonic Context Of Basin Initiation and The Role Of The Pmentioning

confidence: 99%

The role of the Polochic Fault as part of the North American and Caribbean Plate boundary: Insights from the infill of the Lake Izabal Basin

et al. 2020

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The Lake Izabal Basin in Guatemala is a major pull-apart basin along the sinistral Polochic Fault, which is part of the North American and Caribbean plate boundary. The basin infill contains information about the tectonic and sedimentological processes that have imparted a significant control on its sedimentary section. The inception of the basin has been linked to the relative importance of the Polochic Fault in the tectonic history of the plate boundary; yet, its sedimentological record and its inception age have been poorly documented. This study integrates diverse datasets, including industry reports, well logs and reports, well cuttings, vintage seismic data, outcrop observations and geochronological data to constrain the initial infill and age of inception of the basin. The integrated data show that during the Oligocene-Miocene, a marine carbonate platform was established in the region which was later uplifted and eroded in the early Miocene. The fluvial-lacustrine deposits above this carbonate platform are part of the initial infill of the basin and are constrained with zircon weighted-mean 206 Pb/ 238 U ages of 12.060 ± 0.008 from a volcanic tuff ~30 m above the unconformity. Sandstone, mudstone and coal dominate the interval from 12 to 4 Ma, with an increase in conglomerate correlating to the uplift of the Mico Mountains and San Gil Hill at 4 Ma. Fault switch activity between the Polochic and Motagua faults has been hypothesized to explain total offset along the Polochic Fault and the geologic and geodetic slip rates along the two faults. The 12 Ma age determined for the initial infill of the basin confirms this hypothesis. Consequently, our study confirms that at ~12 Ma the Polochic Fault served as the main fault of the plate boundary with inferred slip rates ranging from 13 to 21 mm/yr with a strong possibility that the Polochic Fault was, at some point between 15 Ma and 7 Ma, the only active fault of the plate boundary. The results of this study show that tectonic records preserved in sediments of strike-slip basins improve the understanding of the relative significance of individual faults and the implications with respect to strain partitioning throughout its tectonic history.

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A kinematic model for the evolution of the Eastern California Shear Zone and Garlock Fault, Mojave Desert, California

Dixon

Xie

2018

Earth and Planetary Science Letters

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How fault evolution changes strain partitioning and fault slip rates in Southern California: Results from geodynamic modeling

Cited by 20 publications

References 87 publications

Kinematics and Evolution of the Southern Eastern California Shear Zone, Based on Analysis of Fault Strike, Distribution, Activity, Roughness, and Secondary Deformation

Kinematics and Evolution of the Southern Eastern California Shear Zone, Based on Analysis of Fault Strike, Distribution, Activity, Roughness, and Secondary Deformation

The role of the Polochic Fault as part of the North American and Caribbean Plate boundary: Insights from the infill of the Lake Izabal Basin

A kinematic model for the evolution of the Eastern California Shear Zone and Garlock Fault, Mojave Desert, California

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