Towards a Geodynamic Model of Restraining Bends in Strike-slip Faults - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Towards a Geodynamic Model of Restraining Bends in Strike-slip Faults write by María Helga Guðmundsdóttir. This book was released on 2012. Towards a Geodynamic Model of Restraining Bends in Strike-slip Faults available in PDF, EPUB and Kindle.
Tectonics of Strike-slip Restraining and Releasing Bends
Tectonics of Strike-slip Restraining and Releasing Bends - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Tectonics of Strike-slip Restraining and Releasing Bends write by W. D. Cunningham. This book was released on 2007. Tectonics of Strike-slip Restraining and Releasing Bends available in PDF, EPUB and Kindle. This volume addresses the tectonic complexity and diversity of strike-slip restraining and releasing bends with 18 contributions divided into four thematic sections: a topical review of fault bends and their global distribution; bends, sedimentary basins and earthquake hazards; restraining bends, transpressional deformation and basement controls on development; releasing bends, transtensional deformation and fluid flow.
Control of Rupture Behavior by a Restraining Double-bend from Slip Rates on the Altyn Tagh Fault
Control of Rupture Behavior by a Restraining Double-bend from Slip Rates on the Altyn Tagh Fault - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Control of Rupture Behavior by a Restraining Double-bend from Slip Rates on the Altyn Tagh Fault write by Austin John Elliott. This book was released on 2014. Control of Rupture Behavior by a Restraining Double-bend from Slip Rates on the Altyn Tagh Fault available in PDF, EPUB and Kindle. Geometric complexities such as bends and stepovers along strike-slip faults impact the propagation of earthquake ruptures and can control the ultimate sizes of earthquakes. The ability of a rupture to propagate through a geometric complexity constitutes a fundamental predictor of seismic hazard, as the resulting length of a seismic fault rupture dictates the extent, intensity, and duration of damaging ground motion. Simulations of individual ruptures along a simple fault system indicate that bends of sufficient length or angle halt earthquake ruptures, yet simulations of rupture over multiple seismic cycles reveal that specific local geometry and the history of prior ruptures further modulate this behavior. Thus, assessing the proportion of ruptures that terminate at versus propagate through a geometric complexity requires specific geologic observations of fault geometry and seismic history. To investigate to what extent geometry alone controls rupture length, and validate the predictions of numerical models with observational data, I investigate the geomorphic record of multiple Quaternary earthquake cycles at the Aksay restraining double-bend on the Altyn Tagh fault (ATF) in western China. At the Aksay bend two overlapping subparallel strike-slip faults (the northern--NATF--and southern--SATF--Altyn Tagh faults) permit testing of model predictions for different fault bend angles. First I document the size and extent of the most recent earthquake (MRE) along the SATF, mapping 95 km of continuous fresh rupture as well as 70 measurements of small offsets that represent average coseismic slip of 5.6 m. Importantly, I constrain the eastward extent of this MRE and several before it at the most highly misoriented reach of the Aksay bend. Through Beryllium-10 exposure age dating of an undeformed Pleistocene alluvial deposit covering the fault, I demonstrate that no other Quaternary ruptures of the SATF have propagated farther through the bend than the MRE. Together with 270 km of fresh rupture previously mapped to the west, this minimum rupture length of 95 km, and average slip of 5.6 m, indicate a large magnitude M(w)>7.8) for this event. I measure Quaternary slip-rates at four locations spanning the bend on each of the two faults, in order to assess, using accumulated slip, how frequently and where prior ruptures have terminated within the bend. I present a new geomorphic interpretation of the controversial Huermo Bulak He slip rate site on the eastern NATF, at which prior studies reported contradictory slip rates based on conflicting mapping. The rate I determine of 6.3 (+2.1)/(-1.6) mm/yr−1 is substantially lower than some earlier estimates at this site, but agrees with rates determined here from both geodetic modeling and older offset geomorphic markers. At this site and the others I employ optically stimulated luminescence (OSL) burial-age dating of surface-capping loess deposits to interpret abandonment ages of geomorphic surfaces. Using cross-cutting relationships to interpret geomorphic history of deposition and incision at these sites, I relate these surface ages to offset piercing lines to obtain time-averaged slip rates. The resulting distribution of slip rates on each fault define opposing gradients on the west side of the Aksay bend, ranging from 6.3 (+2.1)/(-1.6) mm/yr−1 in the east to 2.1 ± 0.7 mm/yr−1 in the west on the NATF over a 150 km length of fault, but declining abruptly within 50 km on the SATF from 4.1 ± 0.4 mm/yr−1 in the west to effectively zero in the middle of the bend, with only a fraction of the fault-zone slip rate accommodated locally in the east (0.8 ± 0.3 mm/yr−1). This distribution of slip rates indicates that ruptures repeatedly stop at the bend on the SATF, but propagate through on the NATF. These slip gradients reveal persistence of a geometric barrier along the SATF through multiple earthquake cycles, and suggest the absence of a barrier on the NATF. These observed slip rates agree well with the synthetic slip rate distributions derived from numerical models of multiple rupture cycles along the Aksay bend fault system, validating the physics-based behavior in the models. These models, developed by collaborators in parallel with this observational study, provide the extents and distributions of individual earthquake ruptures that sum to produce the long-term slip rates, presenting the ensemble of possible ruptures that geology alone cannot distinguish. Together, the observational results presented here and the corresponding model results indicate that the vast majority of large ruptures halt along the most highly misoriented reach of the SATF, but that the less misoriented NATF remains favorable for occasional rupture. These results demonstrate that numerical modeling, tuned by field observations, may offer probabilistic estimates of the proportion of ruptures that violate expected barriers to propagation and thus generate larger, more damaging earthquakes.
Strike-slip Deformation, Basin Formation, and Sedimentation
Strike-slip Deformation, Basin Formation, and Sedimentation - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Strike-slip Deformation, Basin Formation, and Sedimentation write by Kevin T. Biddle. This book was released on 1985. Strike-slip Deformation, Basin Formation, and Sedimentation available in PDF, EPUB and Kindle. The volume is organized into three sections entitled Overview, Extensional Settings and Contractional Settings together with a glossary of terms having to do with strike-slip deformation, basin formation and sedimentation.
Deformational mechanisms along active strike-slip faults
Deformational mechanisms along active strike-slip faults - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Deformational mechanisms along active strike-slip faults write by Stacey Ann Tyburski. This book was released on 1992. Deformational mechanisms along active strike-slip faults available in PDF, EPUB and Kindle. The northwest part of the North America-Caribbean plate boundary zone is characterized by active, left-lateral strike-slip faults that are well constrained seismically and are corroborated by on- and offshore geologic mapping. The onshore plate boundary zone comprises the Motogua and Polochic fault systems of southern Guatemala which join and continue offshore as the Swan Islands fault zone along the southern edge of the Cayman trough. At the Mid-Cayman spreading center in the central Caribbean Sea, the fault motion is transferred at a 100 km wide left-step in the fault system to the Oriente fault zone. A third system, the Walton fault zone, continues east from the Mid-Cayman Spreading center to define the Gonave microplate. Seafloor features produced by strike-slip faulting along the Swan Islands and Walton fault zones have been imaged and mapped using the SeaMARC II side-scan sonar and swath bathymetric mapping system, single-channel seismic data, multichannel seismic data and 3.5 kHz depth profiles. Structures mapped along the Swan Islands and Walton fault zones include: 1) twenty-six restraining bends and five releasing bends ranging in size from several kilometers in area to several hundred kilometers in area; 2)en echelon folds which occur only within the restraining bends; 3) straight, continuous fault segments of up to several tens of kilometers in length; 4) restraining and releasing bends forming in "paired" configurations; and 5) a fault-parallel fold belt fold and thrust belt adjacent to a major restraining bend. The features observed along the Swan Islands and Walton fault systems are compared to other features observed along other strike-slip fault systems, from which empirical models have previously been derived. Based on the features observed in these strike-slip systems, a rigid plate scenario is envisioned where the geometry of the fault and the direction of plate motion have controlled the types of deformation that have occurred. In a related study, microtectonic features in an area of Neogene extension within the northwestern Caribbean plate were investigated in order to provide insight on the nature of intraplate deformation related to the motion along the plate boundary. Microtectonic features were measured in the Sula-Yojoa rift of northwestern Honduras with the intention of inverting the data to estimate stress states responsible for the observed strains. Data inversion for the estimation of stress states could not be undertaken with the available measurements, however, the observations made can be used to support several existing models for the intraplate deformation as well as to encourage the elimination of other models.
