Waveform inversion for 3-D S-velocity structure of D′′ beneath the Northern Pacific: possible evidence for a remnant slab and a passive plume

Abstract We conduct waveform inversion to infer the three-dimensional (3-D) S-velocity structure in the lowermost 400 km of the mantle (the D′′ region) beneath the Northern Pacific region. Our dataset consists of about 20,000 transverse component broadband body-wave seismograms observed at North Ame...

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Bibliographic Details
Main Authors: Suzuki, Yuki, Kawai, Kenji, Geller, Robert, Borgeaud, Anselme, Konishi, Kensuke
Format: Article in Journal/Newspaper
Language:unknown
Published: Figshare 2016
Subjects:
29999 Physical Sciences not elsewhere classified
FOS Physical sciences
Medicine
Evolutionary Biology
FOS Biological sciences
59999 Environmental Sciences not elsewhere classified
FOS Earth and related environmental sciences
80699 Information Systems not elsewhere classified
FOS Computer and information sciences
Inorganic Chemistry
FOS Chemical sciences
Hematology
110309 Infectious Diseases
FOS Health sciences
Pacific
Kamchatka Peninsula
Kamchatka
Online Access:https://dx.doi.org/10.6084/m9.figshare.c.3597902
https://figshare.com/collections/Waveform_inversion_for_3-D_S-velocity_structure_of_D_beneath_the_Northern_Pacific_possible_evidence_for_a_remnant_slab_and_a_passive_plume/3597902
Description
Summary:Abstract We conduct waveform inversion to infer the three-dimensional (3-D) S-velocity structure in the lowermost 400 km of the mantle (the D′′ region) beneath the Northern Pacific region. Our dataset consists of about 20,000 transverse component broadband body-wave seismograms observed at North American stations for 131 intermediate and deep earthquakes which occurred beneath the western Pacific subduction region. We use S, ScS, and other phases that arrive between them. Resolution tests indicate that our methods and dataset can resolve the velocity structure in the target region with a horizontal scale of about 150 km and a vertical scale of about 50 km. The 3-D S-velocity model obtained in this study shows three prominent features: (1) prominent sheet-like lateral high-velocity anomalies up to $$\sim$$ ∼ 3% faster than the Preliminary Reference Earth Model (PREM) with a thickness of $$\sim$$ ∼ 200 km, whose lower boundary is $$\sim$$ ∼ 150 km above the core–mantle boundary (CMB). (2) A prominent low-velocity anomaly block located to the west of the Kamchatka peninsula, which is $$\sim$$ ∼ 2.5% slower than PREM, immediately above the CMB beneath the high-velocity anomalies. (3) A relatively thin ( $$\sim$$ ∼ 300 km) low-velocity structure continuous from the low-velocity anomaly “(2)” to at least 400 km above the CMB. We also detect a continuous low-velocity anomaly from the east of the Kamchatka peninsula at an altitude of 50 km above the CMB to the far east of the Kuril islands at an altitude of 400 km above the CMB. We interpret these features respectively as: (1) remnants of slab material where the bridgmanite to Mg-post-perovskite phase transition may have occurred within the slab, (2, 3) large amounts of hot and less dense materials beneath the cold Kula or Pacific slab remnants just above the CMB which ascend and form a passive plume upwelling at the edge of the slab remnants. Graphical Abstract .

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