Crustal Shear Wave Velocity Structure of Central Idaho and Eastern Oregon From Ambient Seismic Noise: Results From the IDOR Project

Bremner, P. M.; Panning, M. P.; Russo, R. M.; Mocanu, V.; Stanciu, A. C.; Torpey, M. E.; Hongsresawat, S.; VanDecar, J. C.; LaMaskin, Todd A.; Foster, David A.

doi:10.1029/2018jb016350

Cited by 5 publications

(8 citation statements)

References 79 publications

(211 reference statements)

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“…Although there are some hot springs near Stanley (Druschel & Rosenberg, 2001), the moment tensor of the 2020 Stanley earthquake has such a large overall nondouble couple that minor geothermal activity cannot account for it. In addition, strong anisotropy sufficient to affect the long‐period waves used in the moment tensor inversions is unlikely in the shallow crust of the Stanley earthquake region (Bremner et al., 2019; Christian Stanciu et al., 2016). Based on the back‐projection results, InSAR ground deformation and aftershock distribution, we favor a multifault rupture process to explain the significant nondouble‐couple in the moment tensors of the Stanley earthquake.…”

Section: Discussionmentioning

confidence: 99%

“…The teleseismic data include 72 P wave and 37 SH-wave ground displacement recordings that are filtered in the frequency band from 0.005 to 0.9 Hz (Figure S3). The structural model used in the inversion is the local model (Bremner et al, 2019;Christian Stanciu et al, 2016;Davenport et al, 2017;Laske et al, 2013 maximum rupture velocity is set to 4 km/s. The subfault durations and rupture velocity are both relatively large for the small subfault dimensions, but this is allowed in order to accommodate the uncertainty in the hypocentral position.…”

Section: Finite-fault Inversion For Teleseismic Datamentioning

confidence: 99%

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Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake

Yang

Zhu

Lay

et al. 2021

Geophysical Research Letters

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An integrative analysis is applied for the seismological and geodetic data of the 2020 Stanley, Idaho earthquake.• We found that the Stanley earthquake ruptured a pair of opposing-dip faults offset by a 10-km-wide step that narrows with depth.• This study reveals that complicated rupture processes appear to be typical for the earthquakes located near the northern Centennial Tectonic Belt boundary.

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Section: Discussionmentioning

confidence: 99%

Section: Finite-fault Inversion For Teleseismic Datamentioning

confidence: 99%

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake

Yang

Zhu

Lay

et al. 2021

Geophysical Research Letters

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“…The Stanley earthquake initiated near the intersection of the Idaho Batholith and Basin and Range Province of central Idaho near the northern termination of the Quaternary NWtrending Sawtooth normal fault at its junction with Eocene NE-trending Trans-Challis fault system (Figure 2; . Although these two provinces contain different crustal rocks, regional models suggest similar velocities throughout the epicentral region (Stanciu et al, 2016;Davenport et al, 2017;Bremner et al, 2019).…”

Section: Local Velocity Modelmentioning

confidence: 99%

“…This study also identified reflected returns in the middle to lower crust that may be relevant to this study (e.g., brittle-ductile transition). Bremner et al (2019) used the same station array as the Stanciu et al (2016) study, but utilized surface wave information to derive crustal Vs models. We extracted the closest velocity model to the Stanley earthquake location from each of the three studies to derive our local Vp and Vs models (Figure 3).…”

Section: Local Velocity Modelmentioning

confidence: 99%

Data Analysis of the 2020 Central Idaho Mainshock-Aftershock Sequence

Liberty

Mikesell

Wilbur

2021

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In an effort to inform the Senior Seismic Hazard Analysis Committee (SSHAC) Level 3 project for the Idaho National Laboratory, we provide an improved aftershock catalog related to the March 31, 2020, Mw6.5 Stanley, Idaho earthquake from picks related to a temporary network of two real-time and 15 non-telemetered seismometers within the epicentral area. From the permanent and temporary (XP) real-time network, the USGS cataloged 1,946 aftershocks between April 1, 2020 and October 31, 2020. To improve aftershock location and magnitudes, we manually picked arrival times of P and S waves from off-line stations in the XP temporary network, generated a new crustal velocity model, and independently relocated each event using the HypoDD double-difference earthquake algorithm. We created our new velocity model from existing broadband and active source seismic campaign data that were acquired near the epicentral region prior to the 2020 earthquake. We compare arrival time differences, epicentral locations and depths between aftershocks recorded with the two catalogs. We find the addition of local stations provides tighter aftershock clustering that suggests an improved aftershock locations. To detect lower magnitude events, we employed deep learning. Our method solves common problems associated with detecting many events that have a low signal-to-noise ratio. From the machine learning database, we detected more than 74,000 aftershocks. Based on the number of identified earthquakes and Gutenberg-Richter relationships derived from the USGS catalog, we estimate that we have reduced the completion magnitude for the Stanley earthquake sequence to below M1 using this machine learning approach. We located each aftershock with our new velocity model. Our new velocity model and picks suggests aftershocks occurred mostly at shallower depths than assessed in the USGS catalog. These aftershocks align along two linear trends that suggest the activation of two unnamed primary faults.

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“…Although reasonable sound speeds in the atmosphere vary by only a few percent, for example, 322 m/ s < c < 332 m/s (for temperatures −15°C to 0°C), the speeds of the seismic phases that may excite ground displacement are far more variable and less well constrained. Our analysis does not attempt to determine which seismic wave type is most "infrasonogenic," but instead locates sources for a range of potential seismic wave speeds, from P wave velocities of 5.6 km/s to S wave velocities of 3.2 km/s (see Supporting Information S1 analysis as well as the inferred velocity structure below 2 km from Bremner et al, 2019, andDavenport et al, 2017). Modeled surface wave speeds used here are limited to 1.4 km/s or faster given the prevalence of exposed crystalline rock in the region.…”

Section: 1029/2020gl091421mentioning

confidence: 99%

Mapping the Sources of Proximal Earthquake Infrasound

Johnson

Mikesell

Anderson

et al. 2020

Geophysical Research Letters

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We recorded a M WR 3.6 earthquake in Idaho (USA) on 7 April 2020 with a network of six three-element infrasound arrays and co-located broadband seismometers situated within 25 km of the hypocenter. Infrasound array processing is used to identify the arrival of seismic-to-atmospheric coupled phases and as much as 90 s of infrasound coda. Apparent velocities ranging from seismic speeds to subhorizontal atmospheric sound speeds are attributed to a superposition of coincident waves arriving at the arrays. We find that the arriving infrasound originates from a broad range of back azimuths that deviates from epicentral back azimuth and indicates the ubiquity of secondary radiators for this relatively small earthquake. Secondary radiators, which often locate in regions of elevated topography, are identified using backprojections and earthquake initiation time. Analysis of infrasound sources from proximal earthquakes can be used to map ground shaking distributions, which are important for assessment of earthquake hazards. Plain Language Summary Earthquakes are known to produce sounds, which encompass frequencies that are both perceptible and below the threshold of human hearing. Low frequency earthquake (infra)sound may be recorded with specialized microphones to understand how earthquakes shake Earth's surface. Our study uses six infrasonic microphone stations to detect and locate sound sources for a magnitude 3.6 earthquake that occurred within 25 km of the stations. The recorded infrasound is produced by ground shaking at both the infrasound stations and also over a wide distribution of areas coinciding with mountain topography. These secondary sources of earthquake sounds occur as seismic waves pass by and the resultant ground shaking perturbs the atmosphere. The identification of infrasound in this study is possible even though the earthquake size is relatively small.

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Crustal Shear Wave Velocity Structure of Central Idaho and Eastern Oregon From Ambient Seismic Noise: Results From the IDOR Project

Cited by 5 publications

References 79 publications

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake

Data Analysis of the 2020 Central Idaho Mainshock-Aftershock Sequence

Mapping the Sources of Proximal Earthquake Infrasound

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Crustal Shear Wave Velocity Structure of Central Idaho and Eastern Oregon From Ambient Seismic Noise: Results From the IDOR Project

Cited by 5 publications

References 79 publications

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 Mw 6.5 Stanley, Idaho Earthquake

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 Mw 6.5 Stanley, Idaho Earthquake

Data Analysis of the 2020 Central Idaho Mainshock-Aftershock Sequence

Mapping the Sources of Proximal Earthquake Infrasound

Contact Info

Product

Resources

About

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake

Multifault Opposing‐Dip Strike‐Slip and Normal‐Fault Rupture During the 2020 M_w 6.5 Stanley, Idaho Earthquake