Imaging Subduction Beneath Mount St. Helens: Implications for Slab Dehydration and Magma Transport

Mann, Michael Everett; Abers, G. A.; Crosbie, Kayla; Creager, K. C.; Ulberg, C. W.; Moran, S. C.; Rondenay, S.

doi:10.1029/2018gl081471

Cited by 20 publications

(34 citation statements)

References 45 publications

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“…(k) Gradient model at 60‐km depth. In (h)–(k), purple contour shows the subducting oceanic crust (OC) at this depth, from Mann et al (). Yellow triangles show major volcanoes.…”

Section: Resultsmentioning

confidence: 99%

“…(c) E‐W Vs transect through the gradient model passing through MSH. Black line shows oceanic Moho from Mann et al (); plate interface is 6 km shallower. (d) Same for the Moho model.…”

Section: Resultsmentioning

confidence: 99%

“…The Moho discontinuity disappears within a couple kilometers west of the MSH edifice in Pn amplitudes (Brocher et al, ), PmP reflections (Hansen et al, ), and receiver functions (Mann et al, ). Likewise, the surface‐wave tomography presented here shows steep velocity gradients across the Moho to the east and very weak velocity gradients in the west, although the amplitude of the Moho step is sensitive to the initial model (Figures and S9).…”

Section: Discussionmentioning

confidence: 99%

“…Vertical slice follows Figure c, and top surface shows Vs at 2.5‐km depth. Blue/red shading overlay on cross‐section shows migrated receiver function image of Mann et al (). Colors on vertical slice are shaded combination of the surface‐wave color scale (SW) and that for receiver functions (RF).…”

Section: Discussionmentioning

confidence: 99%

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Shear Velocity Structure From Ambient Noise and Teleseismic Surface Wave Tomography in the Cascades Around Mount St. Helens

et al. 2019

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Mount St. Helens (MSH) lies in the forearc of the Cascades where conditions should be too cold for volcanism. To better understand thermal conditions and magma pathways beneath MSH, data from a dense broadband array are used to produce high‐resolution tomographic images of the crust and upper mantle. Rayleigh‐wave phase‐velocity maps and three‐dimensional images of shear velocity (Vs), generated from ambient noise and earthquake surface waves, show that west of MSH the middle‐lower crust is anomalously fast (3.95 ± 0.1 km/s), overlying an anomalously slow uppermost mantle (4.0–4.2 km/s). This combination renders the forearc Moho weak to invisible, with crustal velocity variations being a primary cause; fast crust is necessary to explain the absent Moho. Comparison with predicted rock velocities indicates that the fast crust likely consists of gabbros and basalts of the Siletzia terrane, an accreted oceanic plateau. East of MSH where magmatism is abundant, middle‐lower crust Vs is low (3.45–3.6 km/s), consistent with hot and potentially partly molten crust of more intermediate to felsic composition. This crust overlies mantle with more typical wave speeds, producing a strong Moho. The sharp boundary in crust and mantle Vs within a few kilometers of the MSH edifice correlates with a sharp boundary from low heat flow in the forearc to high arc heat flow and demonstrates that the crustal terrane boundary here couples with thermal structure to focus lateral melt transport from the lower crust westward to arc volcanoes.

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“…(k) Gradient model at 60‐km depth. In (h)–(k), purple contour shows the subducting oceanic crust (OC) at this depth, from Mann et al (). Yellow triangles show major volcanoes.…”

Section: Resultsmentioning

confidence: 99%

“…(c) E‐W Vs transect through the gradient model passing through MSH. Black line shows oceanic Moho from Mann et al (); plate interface is 6 km shallower. (d) Same for the Moho model.…”

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Shear Velocity Structure From Ambient Noise and Teleseismic Surface Wave Tomography in the Cascades Around Mount St. Helens

et al. 2019

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“…The downdip width of volcanism in this region is anomalously wide compared to the entire Cascades arc (Figure S1; Hildreth, ). Previous explanations for this behavior have included a slab tear or hole (Darold & Humphreys, ; Michaelson & Weaver, ), though analysis of receiver functions shows no evidence for a tear near MSH (Mann et al, ), or lateral migration of melt somewhere between the subducting slab and the upper crust (Hansen et al, ; Kiser et al, ). With regard to volcanism at MSH and Indian Heaven, upper crustal control has also been posited (Bedrosian et al, ).…”

Section: Introductionmentioning

confidence: 99%

Local Source Vp and Vs Tomography in the Mount St. Helens Region With the iMUSH Broadband Array

Ulberg

Creager

Moran

et al. 2020

Geochem Geophys Geosyst

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We present new 3‐D P wave and S wave velocity models of the upper 20 km of the Mount St. Helens (MSH) region. These were obtained using local‐source arrival time tomography from earthquakes and explosions recorded at 70 broadband stations deployed as part of the imaging Magma Under St. Helens (iMUSH) project and augmented by several data sets. Principal features of our models include (1) low P wave and S wave velocities along the St. Helens seismic zone to depths of at least 20 km corresponding to high conductivity imaged by iMUSH magnetotelluric studies. This delineates a zone of weakness that magma can exploit at the location of MSH; (2) a 5‐ to 7‐km diameter, 6–15 km deep, 3–6% negative P wave and S wave velocity anomaly beneath MSH, consistent with previous estimates of the source region for recent eruptions. We interpret this as a magma storage region containing up to 15–20 km3 of partial melt, which is about 5 times more than the largest documented eruption at MSH; (3) a broad region of low P wave velocity below 10‐km depth extending between Mount Adams and Mount Rainier along and to the east of the main Cascade arc, which is likely due to high‐temperature arc crust and possible presence of fluids or melt; (4) several anomalies associated with surface‐mapped features, including high‐velocity igneous units such as the Spud Mountain and Spirit Lake plutons and low velocities in the Chehalis sedimentary basin and the Indian Heaven volcanic field. Our results place further constraints on the geometry of these features at depth.

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Seismic discrimination of controlled explosions and earthquakes near Mount St. Helens using P/S ratios

Wang¹,

Schmandt²,

Kiser

2020

Preprint

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Explosions and earthquakes are effectively discriminated by P/S amplitude ratios for moderate magnitude events (M[?]4) observed at regional to teleseismic distances ([?]200 km). It is less clear if P/S ratios are effective explosion discriminants for lower magnitudes observed at shorter distances. We report new tests of P/S discrimination using a dense seismic array in a continental volcanic arc setting near Mount St. Helens, with 23 single-fired borehole explosions (ML 0.9-2.3) and 406 earthquakes (ML 1-3.3). The array provides up to 95 three-component broadband seismographs and most source-receiver distances are <120 km. Additional insight is provided by ˜3,000 vertical component geophone recordings of each explosion. Potential controls on local distance P/S ratios are investigated, including: frequency range, distance, magnitude, source depth, number of seismographs, and site effects. A frequency band of about 10-18 Hz performs better than lower or narrower bands because explosion-induced S-wave amplitudes diminish relative to P for higher frequencies. Source depth and magnitude exhibited weak influences on P/S ratios. Site responses for earthquakes and explosions are correlated with each other and with shallow crustal Vp and Vs from travel-time tomography. Overall, the results indicate high potential for local distance P/S explosion discrimination in a continental volcanic arc setting, with [?]98% true positives and [?]6.3% false positives when using the array median from [?]16 stations. Performance is reduced for smaller arrays, especially those with [?]4 stations, thereby emphasizing the importance of array data for discrimination of low magnitude explosions.

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Imaging Subduction Beneath Mount St. Helens: Implications for Slab Dehydration and Magma Transport

Cited by 20 publications

References 45 publications

Shear Velocity Structure From Ambient Noise and Teleseismic Surface Wave Tomography in the Cascades Around Mount St. Helens

Shear Velocity Structure From Ambient Noise and Teleseismic Surface Wave Tomography in the Cascades Around Mount St. Helens

Local Source Vp and Vs Tomography in the Mount St. Helens Region With the iMUSH Broadband Array

Seismic discrimination of controlled explosions and earthquakes near Mount St. Helens using P/S ratios

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