Seismic attenuation tomography of the Mariana subduction system: Implications for thermal structure, volatile distribution, and slow spreading dynamics

Pozgay, S.; Wiens, Douglas A.; Conder, J. A.; Shiobara, Hajime; Sugioka, Hiroko

doi:10.1029/2008gc002313

Cited by 94 publications

(163 citation statements)

References 105 publications

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“…Taking into account that Q P /Q S for a Poisson solid with null bulk attenuation (Q K À1 ) is close to 2.25 [Jackson, 2007], the present result showing significantly smaller ratio (Q P M /Q S M < 1.0) suggests the presence of melt and/or scattering attenuation in the mantle beneath Spain [Budiansky et al, 1983]. Q P M /Q S M values found in Southern Spain are lower than: a) those calculated in Central Alaska by Stachnik et al [2004] (Q P /Q S = 1.1 À 1.4), b) those calculated in Tonga-Fiji region [Roth et al, 1999] (Q P /Q S values between 1.7 and 2.2), c) those calculated in the Philippines mantle wedge [Shito and Shibutan, 2003], and at the lower bound of values reported for the Marianas subduction system ($0.8-2.1 [Pozgay et al, 2009]). …”

Section: Results For Q Smentioning

confidence: 93%

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Mancilla

Pezzo

Stich

et al. 2012

Geophysical Research Letters

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[1] Granada (Southern Spain) is a place of rare and enigmatic very deep focus earthquakes, the last one on April 11, 2010, with magnitude of 6.3 and depth of 620 km. We use regional broadband recordings to estimate Q P and Q S in the mantle for frequencies between 0.25 and 8 Hz, computing the spectra of the direct P-and S-waves with their early P-and S coda. We use the spectral decay method, constraining crustal Q to values given in the literature. We obtain robust estimates of Q P in 6 frequency bands (0.25, 0.5,1, 2, 4 and 8 Hz) and of Q S in 4 bands (0.25, 0.5,1, 2 Hz). Q P in the mantle ranges from 13 at 0.25 Hz to 346 at 8 Hz and Q S from 59 at 0.25 to 183 at 2 Hz. The frequency dependence is well fitted by Q = Q 0 f a with a equal to 0.6 for Q S and 1.0 for Q P , and Q 0 equal to 109 for Q S and 63 for Q P . The Q P /Q S ratio is less than 1. These are extreme values within the ranges of mantle Q, Q P /Q S and a values reported in the literature, indicating strong scattering attenuation and absence of melt. We propose that such values, rather than being an exception, may approximate the average upper mantle, with solid olivine composition and small-scale heterogeneity.

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Section: Results For Q Smentioning

confidence: 93%

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Mancilla

Pezzo

Stich

et al. 2012

Geophysical Research Letters

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“…For comparing Q P with Q S in the crust, we also estimate the Q P /Q S structure directly using the S-wave t * data and the estimated Q −1 P structure (Pozgay et al 2009). In the estimation of Q P /Q S , for Q −1 P smaller than 0.0005, we assume Q −1 P = 0.0005.…”

Section: Resultsmentioning

confidence: 99%

Three-dimensional P- and S-wave attenuation structures around the source region of the 2016 Kumamoto earthquakes

Komatsu

Takenaka

Oda

2017

Earth Planets Space

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We investigate the three-dimensional P-and S-wave attenuation (Q −1 P and Q −1 S ) structures of the crust around the source region of the 2016 Kumamoto earthquakes, Japan. To estimate the attenuation structures, the path-averaged attenuation factor t * is estimated from the amplitude decay rate of the P-and S-wave spectra corrected for the source spectrum. The Q −1 P and Q −1 S structures are estimated by tomography using t * for the P-and S-waves, respectively. Several features are found in the attenuation structures as follows: In the source region, two high-Q P and high-Q S zones exist along the Futagawa and the Hinagu fault segments in the upper crust. The high-Q P and high-Q S zone along the Futagawa fault segment is found to include the large-slip area of the mainshock obtained from a source inversion study. In the lower crust, the low Q P is distributed beneath the entire source region. A low-Q P and low-Q S zone also exists beneath the Kuju and Aso volcanoes, which is consistent with the shallow limited depth extent of the seismogenic zone due to high temperature. The western edge of this zone adjoins the eastern edge of the high-Q P and high-Q S area, including the large-slip area.

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“…Previous studies modeled displacement spectra when inverting for path-average attenuation operators [Stachnik et al, 2004;Rychert et al, 2008;Pozgay et al, 2009]. After removing instrument response, our seismograms were in velocity units.…”

Section: Why Acceleration Spectra?mentioning

confidence: 99%

“…We use the Brune model value of k = 0.37 [Pozgay et al, 2009] and estimate Δσ = 30 MPa, and β = 5 km/s. We calculated M 0 for an event from the National Earthquake Information Center database listing of M w using the relation M w = 2/3(log 10 M 0 À 9.1) [Shearer, 1999].…”

Section: Constraining Corner Frequencymentioning

confidence: 99%

Upper mantle Q structure beneath old seafloor in the western Pacific

2014

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The Pacific Lithosphere Anisotropy and Thickness Experiment ocean bottom seismometer array south of the Shatsky Rise allows imaging the attenuation structure of the upper mantle in the oldest parts of the Pacific Ocean. The array consisted of eight seismometers with a lateral extent of 200 km by 600 km. Intermediate-and deep-focus earthquake sources in the Mariana and Izu-Bonin subduction zones provide paths that probe different depths beneath the seafloor. Acceleration spectra from the vertical component of P waves are inverted for the attenuation operator and corner frequency. P n propagation indicates very high Q p values in the lithosphere, of order 1000, while path-average Q p values in the upper mantle are on the order of 400. The variety of source epicentral distances and depths enables us to deduce the vertical Q p À1 structure of the upper mantle. Using the amplitude spectra directly in a weighted least squares problem that accounts for the effects of triplications in the traveltime curves, we invert for Q p À1 as a function of depth. We demonstrate that Q p is frequency dependent and adopt a power law dependence with coefficient α = 0.27. We resolve three distinct layers using a reference frequency of 1 Hz with Q p on the order of 145 at depths 100-250 km, Q p on the order of 350 at depths 250-410 km, and very high Q p with attenuation indistinguishable from zero for depths below 410 km. The P waves have a component of scattering, and thus, Q p À1 represents the maximum intrinsic attenuation beneath normal undisturbed oceanic lithosphere.

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Seismic attenuation tomography of the Mariana subduction system: Implications for thermal structure, volatile distribution, and slow spreading dynamics

Cited by 94 publications

References 105 publications

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Three-dimensional P- and S-wave attenuation structures around the source region of the 2016 Kumamoto earthquakes

Upper mantle Q structure beneath old seafloor in the western Pacific

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Seismic attenuation tomography of the Mariana subduction system: Implications for thermal structure, volatile distribution, and slow spreading dynamics

Cited by 94 publications

References 105 publications

QP and QS in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

QP and QS in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Three-dimensional P- and S-wave attenuation structures around the source region of the 2016 Kumamoto earthquakes

Upper mantle Q structure beneath old seafloor in the western Pacific

Contact Info

Product

Resources

About

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010

Q_P and Q_S in the upper mantle beneath the Iberian peninsula from recordings of the very deep Granada earthquake of April 11, 2010