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1. Evidence for Stress Localization Caused by Lithospheric Heterogeneity From Seismic Attenuation

   https://doi.org/10.1029/2021GC009987  

   Zhu, Zhao; Bezada, Maximiliano J.; Byrnes, Joseph S.; Ford, Heather A. (November 2021, Geochemistry, Geophysics, Geosystems)

   Abstract The Wyoming Craton underwent tectonic modifications during the Laramide Orogeny, which resulted in a series of basement‐cored uplifts that built the modern‐day Rockies. The easternmost surface expression of this orogeny ‐ the Black Hills in South Dakota ‐ is separated from the main trend of the Rocky Mountains by the southern half of the Powder River Basin, which we refer to as the Thunder Basin. Seismic tomography studies reveal a high‐velocity anomaly which extends to a depth of ∼300 km below the basin and may represent a lithospheric keel. We constrain seismic attenuation to investigate the hypothesis that variations in lithospheric thickness resulted in the localization of stress and therefore deformation. We utilize data from the CIELO seismic array, a linear array that extends from east of the Black Hills across the Thunder Basin and westward into the Owl Creek Mountains, the BASE FlexArray deployment centered on the Bighorn Mountains, and the EarthScope Transportable Array. We analyze seismograms from deep teleseismic events and compare waveforms in the time‐domain to characterize lateral variations in attenuation. Bayesian inversion results reveal high attenuation in the Black Hills and Bighorn Mountains and low attenuation in the Thunder and Bighorn Basins. Scattering is rejected as a confounding factor because of a strong anticorrelation between attenuation and the amplitude ofPwave codas. The results support the hypothesis that lateral variations in lithospheric strength, as evidenced by our seismic attenuation measurements, played an important role in the localization of deformation and orogenesis during the Laramide Orogeny. 

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2. Basin Structure for Earthquake Ground Motion Estimates in Urban Los Angeles Mapped with Nodal Receiver Functions

   https://doi.org/10.3390/geosciences13110320  

   Ghose, Ritu; Persaud, Patricia; Clayton, Robert W (November 2023, Geosciences)

   We constrained sedimentary basin structure using a nodal seismic array consisting of ten dense lines that overlie multiple basins in the northern Los Angeles area. The dense array consists of 758 seismic nodes, spaced ~250–300 m apart along linear transects, that recorded ground motions for 30–35 days. We applied the receiver function (RF) technique to 16 teleseismic events to investigate basin structure. Primary basin-converted phases were identified in the RFs. A shear wave velocity model produced in a separate study using the same dataset was incorporated to convert the basin time arrivals to depth. The deepest part of the San Bernardino basin was identified near the Loma Linda fault at a depth of 2.4 km. Basin depths identified at pierce points for separate events reveal lateral changes in basin depth across distances of ~2–3 km near individual stations. A significant change in basin depth was identified within a small distance of ~4 km near the San Jacinto fault. The San Gabriel basin exhibited the largest basin depths of all three basins, with a maximum depth of 4.2 km. The high lateral resolution from the dense array helped to reveal more continuous structures and reduce uncertainties in the RFs interpretation. We discovered a more complex basin structure than previously identified. Our findings show that the basins’ core areas are not the deepest, and significant changes in basin depth were observed near some faults, including the San Jacinto fault, Fontana fault, Red Hill fault and Indian Hill fault. 

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3. New Insights into the Crustal Structure of the San Fernando Valley, California, from a Dense Nodal Seismic Array

   https://doi.org/10.1785/0220240473  

   Juárez-Zúñiga, Alan; Persaud, Patricia (May 2025, Seismological Research Letters)

   Abstract The San Fernando Valley (SFV), a densely populated region in Southern California, has high earthquake hazard due to a complex network of active faults and the amplifying effects of the sedimentary basin. Since the devastating 1994 Mw 6.7 Northridge earthquake, numerous studies have examined its structure using various geological and geophysical datasets. However, current seismic velocity models still lack the resolution to accurately image the near-surface velocity structure and concealed or blind faults, which are critical for high-frequency wavefield simulations and earthquake hazard modeling. To address these challenges, we develop a 3D high-resolution shear-wave velocity model for the SFV using ambient noise data from a dense array of 140 seismic nodes and 10 Southern California Seismic Network stations. We also invert gravity data to map the basin geometry and integrate horizontal-to-vertical spectral ratios and aeromagnetic data to constrain interfaces and map major geological structures. With a lateral resolution of 250 m near the basin center, our model reveals previously unresolved geological features, including the detailed geometry of the basin and previously unmapped structure of faults at depth. The basin deepens from the Santa Monica Mountains in the south to approximately 4 km near its center and 7 km in the Sylmar sub-basin at the basin’s northern margin. Strong velocity contrasts are observed across major faults, at the basin edges, and in the basin’s upper 500 m, for which we measure velocities as low as 200 m/s. Our high-resolution model will enhance ground-motion simulations and earthquake hazard assessments for the SFV and has implications for other urban areas with high seismic risk. 

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4. Crustal Images of the Canada Basin and Its Relationship with the Extinct Mid Oceanic Ridge

   Priyanto, W.S.; Coakley B.J. (December 2023, Transactions of the American Geophysical Union)

   The history of the Canada Basin is poorly understood due to its isolation by distance and ice. The best available evidence suggests the Canada Basin formed during a 66˚ counterclockwise rotation of Northern Alaska away from the Canadian Arctic Islands during the Mesozoic. Gravity and magnetic anomaly data show a linear feature that has been interpreted as an extinct Mid Ocean Ridge, buried under thick turbidites and other sediments. For this study we collected MCS data to constrain the Canada Basin sedimentation history and crustal structure and improve our understanding of the basin. During the summer of 2021, we collected ~4514 km of multichannel-seismic reflection (MCS) data complemented by sonobuoy and OBS data across Canada Basin, Arctic Ocean. The MCS data were acquired with two 520 cu inch GI air guns and a 200 meter (32 channels) streamer. The MCS data was processed by eliminating bad traces, applying a bandpass filter, an FK filter to minimize coherent noise, an FX filter to reduce random noise. The filtered traces were then corrected for normal moveout. This utilized a velocity model from this study area. We then stacked to strengthen the signal and applied post-stack migration to relocate the reflection signal for the effect of dipping reflectors. The seismic profiles close to the Northwind Ridge in the west show a relatively flat basement, with thinner sediments compared to the seismic profile over the inferred mid-oceanic ridge. The seismic profiles crossing the mid-oceanic ridge show a high relief central valley. The basement parallel to the inferred ridge axis is smooth, suggesting the ridge is unsegmented, which is consistent with an ultra-slow spreading mid-oceanic ridge. Origin as an ultra-slow spreading ridge constrains the history of the basin, for example indicating the magnetic striped section of the seafloor, that has been interpreted as oceanic crust, based on sonobuoy refractions results, required 15 - 30 Ma to form. 

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5. Basin structure from a dense nodal seismic array in Yangon, Myanmar: Contributions to seismic hazard estimates

   https://doi.org/10.1190/segam2020-3426695.1  

   Ghose, Ritu; Persaud, Patricia; Thant, Myo; Lin Kyaw, Zaw; Myint Oo, Tin; Myo Win, Zin; Phyo Lwin, Pyae; Chit Min, Aye; Thiha, Thiha; Naing Oo, Thet; et al (September 2020, SEG Technical Program Expanded Abstracts 2020)

   null (Ed.)

   Myanmar is surrounded by complex seismotectonic elements and threatened by a high seismic risk. The Central yanmar Basin (CMB) hosts the largest and fastest growing cities of Myanmar. The CMB is bounded by the Indo- Myanmar subduction zone to the west and the Sagaing fault to the east and is a seismically active tectonic block that has experienced large earthquakes (up to magnitude 8.0). A large earthquake in this region would affect Yangon and its surrounding population of around 8 million. Sedimentary basins have a significant contribution to seismic wave propagation, amplification and duration of ground shaking. Thus, to more accurately estimate the seismic hazard, a clear understanding of the detailed basin structures is required. The goal of our study is to map crustal structures, i.e. crustal thickness, crustal blocks, basin shape, size and depth, fault geometry, dipping layers and intra-crustal layers beneath the Yangon region. We will present receiver functions from a dense array of 168 nodal seismometers with the goal of revealing high-resolution seismic images of the basin. Our dense array will improve basin imaging by reducing uncertainties in receiver function interpretations. Developing a better understanding of basin structures will help our understanding of seismic amplification in the basin and thus will help to more accurately estimate the seismic hazard of this region. 

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