Variations in Lithospheric Thickness Across the Denali Fault and in Northern Alaska

Gama, I.; Fischer, K. M.; Dalton, C. A.; Eilon, Z.

doi:10.1029/2022gl101256

Cited by 8 publications

(23 citation statements)

References 95 publications

(134 reference statements)

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“…We collected eight representative 3-D shear-wave velocity models. Since the arrival of the EarthScope TA in Alaska, there have been a large number of velocity models published using data from the EarthScope TA stations and the Alaska regional network stations (e.g., Jiang et al, 2018;Martin-Short et al, 2018;Gou et al, 2019;Feng & Ritzwoller, 2019;Berg et al, 2020;Yang & Gao, 2020;Esteve et al, 2020;Audet et al, 2019;Nayak et al, 2020;Esteve et al, 2021;Gama et al, 2022b;Liu et al, 2022). To narrow down the velocity models for this synthesis work, we select velocity models that satisfy the following conditions: 1) covers most of mainland Alaska, 2) provides isotropic seismic velocities, 3) uses part or all EarthScope TA data, 4) includes surface wave data to aid with the vertical resolution, 5) is available as a digital velocity model through IRIS Earth Model Collaboration or personal communications, 6) provides absolute velocities or perturbations with an explicitly known reference model, and 7) covers at least the continental crust in depth.…”

Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

“…The EarthScope TA stations have a nominal spacing of about 85 km, while some places, such as central Alaska and the Wrangell Volcanic Field, are covered with denser regional arrays. Among the eight velocity models, the Y2020 model (Yang & Gao, 2020) covers only central and southern Alaska (Figure 2b) while the M2018 (Martin-Short et al, 2018) and G2022 (Gama et al, 2022b) models cover most of Alaska. The rest of the velocity models cover the entire Alaska region.…”

Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

“…The outlines are estimated using the velocity model at the depth of about 30 km for all models. W2018 -model by Ward and Lin (2018), J2018 -model by Jiang et al (2018), M2018 -model by Martin-Short et al (2018), F2019 -model by Feng and Ritzwoller (2019), B2020 -model by Berg et al (2020), Y2020 -model by Yang and Gao (2020), N2020 -model by Nayak et al (2020), G2022 -model by Gama et al (2022b). See Table 1 for more information about these velocity models.…”

Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

“…However, the recent TA deployment has greatly improved the coverage for estimating crustal thickness and allows for continuous analysis across the entire state. Here we compare crustal thickness estimates across Alaska Gao, 2020), N2020 (Nayak et al, 2020), and G2022 (Gama et al, 2022b). Major faults (thick green lines) are shown for reference.…”

Section: Crustal Thickness Modelsmentioning

confidence: 99%

“…In addition to the seven studies selected for comparison, other measures of crustal thickness in Alaska also exist. Among studies that solve for 3D velocity structure, those that jointly invert surface wave dispersion with P receiver functions (e.g., Martin-Short et al, 2018;Feng & Ritzwoller, 2019;Berg et al, 2020) or with S receiver functions (e.g., Gama et al, 2021Gama et al, , 2022b typically provide sharper resolution of the depth of the Moho velocity gradient than other approaches. However, the studies in these groups that sample mainland Alaska are represented in the analysis of shear-wave velocity models in Section 2.1 and their crustal thickness results are not explicitly considered in this section.…”

Section: Crustal Thickness Modelsmentioning

confidence: 99%

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Synthesis of the Seismic Structure of the Greater Alaska Region: Continental Lithosphere

Yang¹,

Mann

Fischer

et al. 2023

Preprint

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Significant advances have been made over the last two decades in constraining the structure of the continental lithosphere in Alaska, particularly with the EarthScope USArray seismic data collection efforts. This paper distills recent seismic models in Alaska and western Yukon (Canada) and relates them to major faults and tectonic terranes. We synthesize results from eight shear-wave velocity models and seven crustal thickness models. Through objective clustering of seismic velocity profiles, we identify six different velocity domains, separately for the crust (at the depth range of 10-50 km) and the mantle (at the depth range of 40-120 km). The crustal seismic domains show strong correlations with average crustal thickness patterns and the distribution of major faults and tectonic terranes. The mantle seismic velocity domains demonstrate signatures of major faults and tectonic terranes in northern Alaska while in southern Alaska the domains are primarily controlled by the geometry of the subducting lithosphere. The results of this study have significant implications for the tectonics and geodynamics of the overriding continental lithosphere from the margin to the interior. This synthesis will be of interest to future studies of Alaska as well as other modern and ancient systems involving convergent margins and terrane accretions.

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Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

Section: -D Shear-wave Velocity Modelsmentioning

confidence: 99%

Section: Crustal Thickness Modelsmentioning

confidence: 99%

Section: Crustal Thickness Modelsmentioning

confidence: 99%

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Synthesis of the Seismic Structure of the Greater Alaska Region: Continental Lithosphere

Yang¹,

Mann

Fischer

et al. 2023

Preprint

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Seismic Imaging of the Westward Transition From Yakutat to Pacific Subduction in Southern Alaska

Millet,

Rondenay,

Bodin

et al. 2023

Geochem Geophys Geosyst

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Alaska is located at the northernmost point of the interface between the Pacific plate and the North American continent. The subduction of the Pacific plate generates arc volcanoes along the Aleutian trench, which stops to the east at the Denali Volcanic Gap. This volcanic gap has been linked to the underthrusting of the Yakutat terrane, which might alter the thermal state of the mantle wedge and prevent melt formation. This implies that the limits of the volcanic activity should mirror the extent of the Yakutat subduction. However, the transition from the Pacific slab to the Yakutat terrane at depth is not fully understood. To investigate this issue, we processed a new composite seismic data set from six arrays deployed in the region from 2000 to 2018. We apply a multi‐mode 3D Kirchhoff migration to obtain high‐resolution 3D scattering images of the region. Our results highlight a sharp lateral boundary in the slab structure, with a 10 km Moho step, just offshore Anchorage, and a more gradual slab transition beneath the southern part of the Kenai peninsula. Our images from the Yakutat slab plunge down to 150 km depth are consistent with previous estimates of the Yakutat slab extent below the Alaska Range. Although the steeply dipping boundaries of the subducting Pacific lithospheres are not fully recovered, deep coherent signals from the Pacific slab are observed down to 150 km depth. These observations suggest that the crust is still partially uneclogitized at these depths in both slabs.

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Variations of Crustal Thickness in Alaska and Northwestern Canada: Implications for Crustal Modification and Accretion of Tectonic Units

Liu,

Gao

2023

JGR Solid Earth

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The northwestern part of North America has recorded multiple tectonic events, such as terrane accretion, strike‐slip motion, and subduction of the Pacific and Yakutat plates, providing an iconic setting to investigate the tectonic evolution of the continental crust. In this study we analyze the receiver functions at seismic stations deployed during 1999–2022 to estimate the crustal thickness, as well as possible slab signature, in Alaska and northwestern Canada. The Moho signal can be clearly detected within the continental region. Specifically, in northwestern Canada, the thickest crust is observed beneath the Cordilleran Deformation Front, which marks the structural boundary between the North American Craton and the North American Margin. We observe a few distinct offsets in the Moho depth located both within the tectonic units and approximately across the major faults between the tectonic units. We provide a first‐order estimate of the depth gradient of the Moho offsets based on the horizontal distance of the two closest seismic stations across the offsets. We propose that the Moho offsets reflect the cumulative impact of the accretionary orogenies and post‐orogenic tectonic events on crustal modification. The continental Moho signal is weak or obscure in Aleutian and southcentral Alaska, and the oceanic Moho within the subducting plates is likely detected. This study provides new seismic insights into understanding the impacts of the tectonic events on continental formation and evolution.

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Variations in Lithospheric Thickness Across the Denali Fault and in Northern Alaska

Cited by 8 publications

References 95 publications

Synthesis of the Seismic Structure of the Greater Alaska Region: Continental Lithosphere

Synthesis of the Seismic Structure of the Greater Alaska Region: Continental Lithosphere

Seismic Imaging of the Westward Transition From Yakutat to Pacific Subduction in Southern Alaska

Variations of Crustal Thickness in Alaska and Northwestern Canada: Implications for Crustal Modification and Accretion of Tectonic Units

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