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Three‐Dimensional P Wave Velocity Structure of the Northern Hikurangi Margin From the NZ3D Experiment: Evidence for Fault‐Bound Anisotropy
Author(s) -
Arai Ryuta,
Kodaira Shuichi,
Henrys Stuart,
Bangs Nathan,
Obana Koichiro,
Fujie Gou,
Miura Seiichi,
Barker Daniel,
Bassett Dan,
Bell Rebecca,
Mochizuki Kimihiro,
Kellett Richard,
Stucker Valerie,
Fry Bill
Publication year - 2020
Publication title -
journal of geophysical research: solid earth
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.983
H-Index - 232
eISSN - 2169-9356
pISSN - 2169-9313
DOI - 10.1029/2020jb020433
Subject(s) - geology , seismology , subduction , anisotropy , slip (aerodynamics) , thrust fault , accretionary wedge , episodic tremor and slip , pacific plate , fault (geology) , geometry , petrology , tectonics , physics , mathematics , quantum mechanics , thermodynamics
We present a high‐resolution three‐dimensional (3‐D) anisotropic P wave velocity ( Vp ) model in the northern Hikurangi margin offshore Gisborne, New Zealand, constructed by tomographic inversion of over 430,000 first arrivals recorded by a dense grid of ocean bottom seismometers. Since the study area covers a region where shallow slow slip events (SSEs) occur repeatedly and the subduction of a seamount is proposed, it offers an ideal location to link our understanding of structural and hydrogeologic properties at megathrust faults to slip behavior. The Vp model reveals an ~30‐km‐wide, low‐velocity accretionary wedge at the toe of the overriding plate, where previous seismic reflection studies show a series of active thrust faults branching from the plate interface. We find some locations with significant Vp azimuthal anisotropy >5% near the branching faults and the deformation front. This finding suggests that the anisotropy is not ubiquitous and homogeneous within the overriding plate, but more localized in the vicinity of active thrust faults. The fast axes of Vp within the accretionary wedge are mostly oriented to the plate convergence direction, which is interpreted as preferentially oriented cracks in a compressional stress regime associated with plate subduction. We find that the magnitudes of anisotropy are roughly equivalent to values found at oceanic spreading centers, where the extensional stress regime is dominant and the crack density is expected to be higher than subduction zones. This consideration may indicate that additional effects such as fault foliation and clay mineral alignment also contribute to upper plate anisotropy along subduction margins.

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