Underwood, Michael B. et al. (2005): Provenance, stratigraphic architecture, and hydrogeologic influence of turbidites on the mid-ocean ridge flank of northwestern Cascadia Basin, Pacific Ocean
Leg/Site/Hole:
Related Expeditions:
ODP 168
Identifier:
ID:
2005-036035
Type:
georefid
Creator:
Name:
Underwood, Michael B.
Affiliation:
University of Missouri-Columbia, Department of Geological Sciences, Columbia, MO, United States
Role:
author
Name:
Hoke, Kimberley D.
Affiliation:
University of California at Santa Cruz, United States
Role:
author
Name:
Fisher, Andrew T.
Affiliation:
Geological Survey of Canada, Canada
Role:
author
Name:
Davis, Earl E.
Affiliation:
University of Bremen, Federal Republic of Germany
Role:
author
Name:
Giambalvo, Emily
Affiliation:
Role:
author
Name:
Zuehlsdorff, Lars
Affiliation:
Role:
author
Name:
Spinelli, Glenn A.
Affiliation:
Role:
author
Identification:
Title:
Provenance, stratigraphic architecture, and hydrogeologic influence of turbidites on the mid-ocean ridge flank of northwestern Cascadia Basin, Pacific Ocean
Year:
2005
Source:
Journal of Sedimentary Research
Publisher:
Society of Economic Paleontologists and Mineralogists, Tulsa, OK, United States
Volume:
75
Issue:
1
Pages:
149-164
Abstract:
The northwestern edge of Cascadia Basin (North Pacific Ocean) is unusual because late Pliocene to Holocene turbidites lap onto juvenile oceanic crust of the Juan de Fuca Ridge. Subsidence of the ridge flank combines with irregular westward progradation of the turbidite facies to create a stratigraphic section that coarsens and thickens upward. The sand provenance is mixed. Individual turbidity currents have funneled into the area through several shelf-slope and abyssal-floor conduits, including Vancouver Valley, Juan de Fuca Channel, Barkley Canyon, and Nitinat Canyon. Local bathymetric blockage, deflection and reflection of flow paths by basement relief, remobilization by intrabasinal submarine slides and debris flows, episodic channel switching, and sporadic overbank flooding have combined to produce erratic recurrence intervals for the turbidity currents. Only the tallest basement highs have remained isolated from turbidite deposition during the last 500,000 years. Spatial and temporal differences in sediment accumulation are important because they modulate the three-dimensional responses of compaction and consolidation. Those changes in physical properties govern where and when hydraulic communication with the underlying basement shuts down. The basal hemipelagic layer of Cascadia Basin transforms to an effective hydrologic seal (seepage rates, 1 mm/yr) once the sediment-basalt interface is buried by 100-150 m of strata. Rapid accumulation of turbidites, therefore, accelerates the hydrogeologic conversion of igneous basement from open to sealed.
Language:
English
Genre:
Serial
Rights:
URL:
Coverage: Geographic coordinates: North:48.0000 West:-129.0000 East:
-127.3000 South:47.4500
Keywords: Quaternary geology; Barkley Canyon; Cascadia Basin; Cenozoic; clastic rocks; clastic sediments; currents; debris flows; East Pacific; hemipelagic environment; hydrogeology; hydrothermal conditions; Juan de Fuca Ridge; Leg 168; marine environment; mass movements; mid-ocean ridges; mud; mudstone; Nitinat Canyon; North Pacific; Northeast Pacific; Ocean Drilling Program; ocean floors; Pacific Ocean; provenance; Quaternary; sedimentary rocks; sediments; sequence stratigraphy; slumping; submarine environment; turbidite; turbidity currents; upper Quaternary; Vancouver Valley;
.