Your search keyword '"*CASCADIA Earthquake, 1700"' showing total 2 results

1. Are great Cascadia earthquakes recorded in the sedimentary records from small forearc lakes?

Author

Morey, A. E., Goldfinger, C., Briles, C. E., Gavin, D. G., Colombaroli, D., and Kusler, J. E.

Subjects

CASCADIA Earthquake, 1700, SEDIMENTARY structures, RADIOCARBON dating, SEDIMENTARY basins

Abstract

Here we investigate sedimentary records from four small inland lakes located in the southern Cascadia forearc region for evidence of earthquakes. Three of these lakes are in the Klamath Mountains near the Oregon-California border, and one is in the central Oregon Coast range. The sedimentary sequences recovered from these lakes are composed of normal lake sediment interbedded with disturbance event layers. The thickest of these layers are graded, and appear to be turbidites or linked debrites (turbidites with a basal debris-flow deposit), suggesting rapid deposition. Variations in particle size and organic content of these layers are reflected in the density and magnetic susceptibility data. The frequency and timing of these events, based on radiocarbon ages from detrital organics, is similar to the offshore seismogenic turbidite record from trench and slope basin cores along the Cascadia margin. Stratigraphic correlation of these anomalous deposits based on radiocarbon ages, down-core density, and magnetic susceptibility data between lake and offshore records suggest synchronous triggering. The areal extent and multiple depositional environments over which these events appear to correlate suggest that these deposits were most likely caused by shaking during great Cascadia earthquakes. [ABSTRACT FROM AUTHOR]

Published

2013

2. Seismoturbidite record as preserved at core sites at the Cascadia and Sumatra-Andaman subduction zones.

Author

Patton, J. R., Goldfinger, C., Morey, A. E., Romsos, C., Black, B., Djadjadihardja, Y., Udrekh, and Meltzner, A.

Subjects

SEDIMENTATION & deposition, TURBIDITES, HYDRODYNAMICS, SLOPES (Physical geography), SUBDUCTION zones, INDIAN Ocean Tsunami, 2004, GEOMORPHOLOGY, CASCADIA Earthquake, 1700, CASCADIA subduction zone

Abstract

Turbidite deposition along slope and trench settings is evaluated for the Cascadia and Sumatra-Andaman subduction zones. Source proximity, basin effects, turbidity current flow path, temporal and spatial earthquake rupture, hydrodynamics, and topography all likely play roles in the deposition of the turbidites as evidenced by the vertical structure of the final deposits. Channel systems tend to promote low-frequency components of the content of the current over longer distances, while more proximal slope basins and base-of-slope apron fan settings result in a turbidite structure that is likely influenced by local physiography and other factors. Cascadia's margin is dominated by glacial cycle constructed pathways which promote turbidity current flows for large distances. Sumatra margin pathways do not inherit these antecedent sedimentary systems, so turbidity currents are more localized. [ABSTRACT FROM AUTHOR]

Published

2013