Downfan transformation from turbidity currents to debris flows at a channel-to-lobe transitional zone; the lower Pleistocene Otadai Formation, Boso Peninsula, Japan

Downfan transformation from turbidity currents to debris flows at a channel-to-lobe transitional zone; the lower Pleistocene Otadai Formation, Boso Peninsula, Japan

Transformation of turbidity currents into debris flows across a channel-to-lobe transition zone was recognized on the basis of lateral mapping of a falling-stage-systems-tract deposit in the lower Pleistocene Otadai Formation submarine-fan sequence on the Boso Peninsula, Japan. The most proximal out...

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Bibliographic Details
Published in:Journal of sedimentary research Vol. 78; no. 10; pp. 668 - 682
Main Author: Ito, Makoto
Format: Journal Article
Language:English
Published: Society for Sedimentary Geology 01-10-2008
Subjects:
Asia
Cenozoic
channels
Chiba Peninsula
clastic rocks
currents
debris flows
Far East
fine-grained materials
Honshu
Japan
lower Pleistocene
marine environment
mass movements
Otadai Formation
outcrops
Pleistocene
Quaternary
Quaternary geology
sedimentary rocks
siltstone
submarine environment
submarine fans
thickness
turbidite
turbidity currents
Japan, Honshu, Chiba Prefect., Boso Peninsula
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Summary:Transformation of turbidity currents into debris flows across a channel-to-lobe transition zone was recognized on the basis of lateral mapping of a falling-stage-systems-tract deposit in the lower Pleistocene Otadai Formation submarine-fan sequence on the Boso Peninsula, Japan. The most proximal outcrops comprise 1 to 4 m thick turbidites, which are laterally equivalent to debrites encased in turbidites in outcrops farther down flow. Such turbidites and encased debrites were deposited from single flow events. The most distal outcrops comprise only thinner (2 to 40 cm thick) turbidites. Debrites contain many siltstone clasts and finer-grained sediments, which are characterized by deep-water faunas and clay-mineral composition similar to those of interbedded hemipelagites. Therefore, the transformation of turbidity currents into debris flows is interpreted to have occurred in response to the incorporation of many siltstone clasts and finer-grained sediment particles into the precursor turbidity currents through erosion of muddy substrates. Subsequently, turbulence in the precursor turbidity currents was suppressed and near-bed flow with higher sediment concentration developed. Intense erosion of muddy substrates is interpreted to have occurred in response to the increase in intensity of turbulence in the precursor turbidity currents at the mouths of middle-fan channels. The precursor turbidity currents (or turbidity currents generated by dilution of debris flows) produced a turbidite deposit, which was subsequently overrun by the debris flow in a proximal lobe environment. The debris flows are interpreted to have subsequently been transformed into turbidity currents, which are recorded by turbidite deposition in the more distal-lobe environment. Debrites can characterize the proximal portion of an attached-lobe deposit in a channel-to-lobe transition zone. Such debrites can be significant heterogeneities for fluid flows in sand-prone successions from middle-fan channel to attached-lobe deposits.
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ISSN:1527-1404
DOI:10.2110/jsr.2008.076