Megathrust splay faults at the focus of the Prince William Sound asperity, Alaska

High‐resolution sparker and crustal‐scale air gun seismic reflection data, coupled with repeat bathymetric surveys, document a region of repeated coseismic uplift on the portion of the Alaska subduction zone that ruptured in 1964. This area defines the western limit of Prince William Sound. Differen...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2013-10, Vol.118 (10), p.5428-5441
Main Authors: Liberty, Lee M., Finn, Shaun P., Haeussler, Peter J., Pratt, Thomas L., Peterson, Andrew
Format: Article
Language:English
Subjects:
Alaska subduction
Applied geophysics
Earth sciences
Earth, ocean, space
Earthquakes
Exact sciences and technology
Fault lines
Faults
Geological faults
Geophysics
Holocene
Internal geophysics
megathrust splay fault
Ocean floor
Plate tectonics
Reflection
Rocks
Seismic activity
Seismic phenomena
Seismic surveys
Seismology
Sound
Surveys
Tectonics. Structural geology. Plate tectonics
Transition zone
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Summary:High‐resolution sparker and crustal‐scale air gun seismic reflection data, coupled with repeat bathymetric surveys, document a region of repeated coseismic uplift on the portion of the Alaska subduction zone that ruptured in 1964. This area defines the western limit of Prince William Sound. Differencing of vintage and modern bathymetric surveys shows that the region of greatest uplift related to the 1964 Great Alaska earthquake was focused along a series of subparallel faults beneath Prince William Sound and the adjacent Gulf of Alaska shelf. Bathymetric differencing indicates that 12 m of coseismic uplift occurred along two faults that reached the seafloor as submarine terraces on the Cape Cleare bank southwest of Montague Island. Sparker seismic reflection data provide cumulative Holocene slip estimates as high as 9 mm/yr along a series of splay thrust faults within both the inner wedge and transition zone of the accretionary prism. Crustal seismic data show that these megathrust splay faults root separately into the subduction zone décollement. Splay fault divergence from this megathrust correlates with changes in midcrustal seismic velocity and magnetic susceptibility values, best explained by duplexing of the subducted Yakutat terrane rocks above Pacific plate rocks along the trailing edge of the Yakutat terrane. Although each splay fault is capable of independent motion, we conclude that the identified splay faults rupture in a similar pattern during successive megathrust earthquakes and that the region of greatest seismic coupling has remained consistent throughout the Holocene. Key Points We document a region of repeated and consistent coseismic uplift Our observations identify tsunami source and earthquake rupture locations Microplate boundary plays a strong role in splay fault formation
ISSN:2169-9313
2169-9356
DOI:10.1002/jgrb.50372