A submarine landslide source for the devastating 1964 Chenega tsunami, southern Alaska

A submarine landslide source for the devastating 1964 Chenega tsunami, southern Alaska

During the 1964 Great Alaska earthquake (Mw 9.2), several fjords, straits, and bays throughout southern Alaska experienced significant tsunami runup of localized, but unexplained origin. Dangerous Passage is a glacimarine fjord in western Prince William Sound, which experienced a tsunami that devast...

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Veröffentlicht in:Earth and planetary science letters 2016-03, Vol.438, p.112-121
Hauptverfasser: Brothers, Daniel S., Haeussler, Peter J., Liberty, Lee, Finlayson, David, Geist, Eric, Labay, Keith, Byerly, Mike
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Sprache:eng
Schlagworte:
Basins
debris flow
Fjords
glacimarine fjord
inverse travel time
Landslides
mass transport
megathrust
Origins
paleoseismology
Sediments
Tsunamis
Villages
Water depth
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container_issue
container_start_page 112
container_title Earth and planetary science letters
container_volume 438
creator Brothers, Daniel S.
Haeussler, Peter J.
Liberty, Lee
Finlayson, David
Geist, Eric
Labay, Keith
Byerly, Mike
description During the 1964 Great Alaska earthquake (Mw 9.2), several fjords, straits, and bays throughout southern Alaska experienced significant tsunami runup of localized, but unexplained origin. Dangerous Passage is a glacimarine fjord in western Prince William Sound, which experienced a tsunami that devastated the village of Chenega where 23 of 75 inhabitants were lost – the highest relative loss of any community during the earthquake. Previous studies suggested the source of the devastating tsunami was either from a local submarine landslide of unknown origin or from coseismic tectonic displacement. Here we present new observations from high-resolution multibeam bathymetry and seismic reflection surveys conducted in the waters adjacent to the village of Chenega. The seabed morphology and substrate architecture reveal a large submarine landslide complex in water depths of 120–360 m. Analysis of bathymetric change between 1957 and 2014 indicates the upper 20–50 m (∼0.7 km3) of glacimarine sediment was destabilized and evacuated from the steep face of a submerged moraine and an adjacent ∼21 km2 perched sedimentary basin. Once mobilized, landslide debris poured over the steep, 130 m-high face of a deeper moraine and then blanketed the terminal basin (∼465 m water depth) in 11±5 m of sediment. These results, combined with inverse tsunami travel-time modeling, suggest that earthquake-triggered submarine landslides generated the tsunami that struck the village of Chenega roughly 4 min after shaking began. Unlike other tsunamigenic landslides observed in and around Prince William Sound in 1964, the failures in Dangerous Passage are not linked to an active submarine delta. The requisite environmental conditions needed to generate large submarine landslides in glacimarine fjords around the world may be more common than previously thought. •New geophysical evidence for a large landslide complex offshore Chenega Island.•Pervasive failure of glacimarine sediment along a perched sedimentary basin.•Earthquake-triggered submarine landslides are likely cause of tsunami in 1964.•Landslides display complex flow evolution from source area to deposition.
doi_str_mv 10.1016/j.epsl.2016.01.008
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source Elsevier ScienceDirect Journals
subjects Basins
debris flow
Fjords
glacimarine fjord
inverse travel time
Landslides
mass transport
megathrust
Origins
paleoseismology
Sediments
Tsunamis
Villages
Water depth
title A submarine landslide source for the devastating 1964 Chenega tsunami, southern Alaska
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