Midcrustal Deformation in the Central Andes Constrained by Radial Anisotropy

Lynner, Colton; Beck, S. L.; Zandt, G.; Porritt, R. W.; Lin, F. C.; Eilon, Z.

doi:10.1029/2017jb014936

Cited by 37 publications

(33 citation statements)

References 107 publications

(198 reference statements)

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“…On the global scale, negative anisotropy has been previously reported in different orogenic foreland belts. For example, radial anisotropy has been reported at 10 km or shallower depths beneath the Central Andean thrust‐and‐fold belt in the Eastern Cordillera of Bolivia (Lynner et al, ). Chen et al () and Guo et al () found Vsv > Vsh with a magnitude of 8–10% beneath the Himalayan fold‐thrust belt.…”

Section: Discussionmentioning

confidence: 99%

“…Within the continental crust, shear wave anisotropy up to 18% has been reported in western‐central Tibet in connection with rock fabrics induced by crustal thinning and channel flow (e.g., Agius & Lebedev, ; Guo et al, ; Ozacar & Zandt, ; Shapiro et al, ). An analog of the Tibetan Plateau is the central Andes, where strong (12–20%) shear wave radial anisotropy is identified at midcrustal depths through receiver function modeling (Leidig & Zandt, ) and inversion of ambient noise data (Lynner et al, ). Significant crustal‐scale anisotropy belies in many other parts of the world, including the Basin and Range Province of western North America where the amplitudes vary from 2 to 6% (e.g., Moschetti et al, ; Xie et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Wang

Chen

2020

JGR Solid Earth

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Deformation‐associated craton assembly and Cordilleran orogenesis played major roles during the crustal formation beneath the western margin of North America. To improve the understanding of the deformation history in this region, we investigate the crustal shear velocity and anisotropy by analyzing fundamental mode Rayleigh and Love waves from ambient seismic noise. Continuous recordings from 118 regional broadband stations reveal lateral variations in both velocity and anisotropy with strong spatial affinities to major geological domains. Strong variations in radial anisotropy, which dips westward and extends to at least midcrustal depths, suggest a “thick‐skinned” foreland thrust‐and‐fold belt beneath the Canadian Rocky Mountains. Our regional data also suggest increased horizontal shear velocities beneath the southern Canadian Cordillera, particularly near the Omineca Belt, which may have resulted from strong zonal deformation within the Cordilleran crust. This anisotropic anomaly migrates southward, and its spatial extent agrees well with the normal fault distribution to the west of the Rocky Mountain Trench. Our observations offer new evidence for the Eocene extension of the orogenic hinterland during the trans‐tensional motion of the Cordillera to the North American craton.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Wang

Chen

2020

JGR Solid Earth

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“…Tectonics orientation (CPO; Mainprice & Nicolas, 1989;Weiss et al, 1999). However, there are plausible alternatives or additional contributions such as preferentially oriented fractures in the shallow crust, sedimentary stratigraphy, and organization of partial melt or fluids that may be prevalent in thick orogenic crust or magmatic systems (Almqvist & Mainprice, 2017;Backus, 1962;Hacker et al, 2014;Harmon & Rychert, 2015;Jaxybulatov et al, 2014;Wang et al, 2020;Leary et al, 1990;Lynner et al, 2018;Matharu et al, 2014). The thin crust of the modern Basin and Range makes pervasive midcrustal melting less likely compared to settings such as the Tibetan plateau, which has about double the thickness of radiogenic heat-producing crust (e.g., Hacker et al, 2014).…”

Section: 1029/2020tc006140mentioning

confidence: 99%

“…Tectonics weakness during MCC formation rather than modern regionally averaged rheology. Sill-like intrusions are interpreted to contribute to strong positive radial anisotropy in active magmatic systems as a result of shape-preferred orientation (SPO) due to large V S contrasts between partially molten and subsolidus crustal rocks (Harmon & Rychert, 2015;Jaxybulatov et al, 2014;Jiang et al, 2018;Lynner et al, 2018). However, crystallized basaltic sills embedded in an intermediate to mafic lower crust may not have large enough velocity contrasts for SPO to cause detectable radial anisotropy (Schmandt et al, 2019).…”

Section: 1029/2020tc006140mentioning

confidence: 99%

“…Crustal radial anisotropy has been detected in other parts of the North American Cordillera including the southern California transform margin (Wang et al, 2020), the Rio Grande rift (Fu & Li, 2015), the Canadian Rockies (Dalton & Gaherty, 2013), and Alaska (Feng & Ritzwoller, 2019). Globally, crustal radial anisotropy has been identified in many continental areas including tectonically active and cratonic settings (Cheng et al, 2013;Dreiling et al, 2018;Duret et al, 2010;Harmon & Rychert, 2015;Huang et al, 2010;Luo et al, 2013;Lynner et al, 2018;Ojo et al, 2017;Sherrington et al, 2004;Xie et al, 2013). The most conventional interpretation for its origin is the strain-induced alignment of anisotropic crustal minerals forming an aggregate crystallographic preferred (Kreemer et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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A Middle Crustal Channel of Radial Anisotropy Beneath the Northeastern Basin and Range

2020

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A challenge in interpreting the origins of seismic anisotropy in deformed continental crust is that composition and rheology vary with depth. We investigated anisotropy in the northeastern Basin and Range where prior studies found prevalent depth‐averaged positive radial anisotropy (VSH > VSV). This study focuses on depth‐dependence of anisotropy and potentially distinct structures beneath three metamorphic core complexes (MCCs). Rayleigh and Love wave dispersion were measured using ambient noise interferometry, and Bayesian Markov chain Monte Carlo inversions for VS structure were tested with several (an)isotropic parameterizations. Acceptable data fits with minimal introduction of anisotropy are achieved by models with anisotropy concentrated in the middle crust. The peak magnitude of anisotropy from the mean of the posterior distributions ranges from 3.5–5% and is concentrated at 8–20 km depth. Synthetic tests with one uniform layer of anisotropy best reproduce the regional mean results with 9% anisotropy at 6–22 km depth. Both magnitudes are plausible based on exhumed middle crustal rocks. The three MCCs exhibit ~5% higher isotropic upper crustal VS, likely due to their anomalous levels of exhumation, but no distinctive (an)isotropic structures at deeper depths. Regionally pervasive middle crustal positive radial anisotropy is interpreted as a result of subhorizontal foliation of mica‐bearing rocks deformed near the top of the ductile deformation regime. Decreasing mica content with depth and more broadly distributed deformation at lower stress levels may explain diminished lower crustal anisotropy. Absence of distinctive deep crustal VS beneath the MCCs suggests overprinting by ductile deformation since the middle Miocene.

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A Middle Crustal Channel of Radial Anisotropy Beneath the Northeastern Basin and Range

Wilgus¹,

Jiang²,

Schmandt³

2020

Preprint

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A challenge in interpreting the origins of seismic anisotropy in deformed continental crust is that composition and rheology vary with depth. We investigated anisotropy in the northeastern Basin and Range where prior studies found prevalent depth-averaged positive radial anisotropy (V SH > V SV ). This study focuses on depth-dependence of anisotropy and potentially distinct structures beneath three metamorphic core complexes (MCCs). Rayleigh and Love wave dispersion were measured using ambient noise interferometry, and Bayesian Markov chain Monte Carlo inversions for V S structure were tested with several (an)isotropic parameterizations. Acceptable data fits with minimal introduction of anisotropy are achieved by models with anisotropy concentrated in the middle crust. The peak magnitude of anisotropy from the mean of the posterior distributions ranges from 3.5-5% and is concentrated at 8-20 km depth. Synthetic tests with one uniform layer of anisotropy best reproduce the regional mean results with 9% anisotropy at 6-22 km depth. Both magnitudes are plausible based on exhumed middle crustal rocks. The three MCCs exhibit ~5% higher isotropic upper crustal V S , likely due to their anomalous levels of exhumation, but no distinctive (an)isotropic structures at deeper depths. Regionally pervasive middle crustal positive radial anisotropy is interpreted as a result of subhorizontal foliation of mica-bearing rocks deformed near the top of the ductile deformation regime. Decreasing mica content with depth and more broadly distributed deformation at lower stress levels may explain diminished lower crustal anisotropy. Absence of distinctive deep crustal V S beneath the MCCs suggests overprinting by ductile deformation since the middle Miocene.

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Midcrustal Deformation in the Central Andes Constrained by Radial Anisotropy

Cited by 37 publications

References 107 publications

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

A Middle Crustal Channel of Radial Anisotropy Beneath the Northeastern Basin and Range

A Middle Crustal Channel of Radial Anisotropy Beneath the Northeastern Basin and Range

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