Wave-enhanced sediment-gravity flows and mud dispersal across continental shelves; reappraising sediment transport processes operating in ancient mudstone successions

Recent studies of marine shelf sediment dispersal show that wave-enhanced sediment-gravity flows are widespread phenomena and can transport large volumes of fluid mud rapidly across low-gradient shelves. Flow evolution is controlled by sediment supply, seabed gradient, and spatial distribution of wa...

Full description

Saved in:
Bibliographic Details
Published in:Geology (Boulder) 2010-10, Vol.38 (10), p.947-950
Main Authors: Macquaker, Joe H. S, Bentley, Samuel J, Bohacs, Kevin M
Format: Article
Language:English
Subjects:
applications
clastic rocks
clastic sediments
Cleveland Ironstone Formation
continental margin sedimentation
Cretaceous
East Pacific
Eel River basin
energy
England
Europe
Geology
gravity flows
Great Britain
Jurassic
Lower Cretaceous
Lower Jurassic
Marine
marine environment
marine sediments
Mesozoic
microstructure
modern analogs
Mowry Shale
mud
mudstone
North Pacific
Northeast Pacific
ocean waves
Pacific Ocean
paleo-oceanography
reworking
sed rocks, sediments
sediment supply
sediment transport
Sedimentary geology
Sedimentary petrology
sedimentary rocks
sedimentation
Sediments
shale
shelf environment
Stratigraphy
transport
United Kingdom
United States
Western Europe
Wyoming
Yorkshire England
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recent studies of marine shelf sediment dispersal show that wave-enhanced sediment-gravity flows are widespread phenomena and can transport large volumes of fluid mud rapidly across low-gradient shelves. Flow evolution is controlled by sediment supply, seabed gradient, and spatial distribution of wave energy at the seabed. Using existing flow models, we predict that such flows in mud-dominated sediments will develop a three-part microstratigraphy produced by changing flow conditions, beginning with wave-induced turbulent resuspension, then development of a wave-enhanced sediment-gravity flow, prior to lutocline collapse and suspension settling. Petrographic examination of modern flow deposits collected from the Eel Shelf reveals that resultant beds possess a microstratigraphy consistent with our hypothesis: a silt-rich basal subunit with curved ripple laminae, abruptly overlain by a subunit composed of continuous intercalated silt/clay laminae, and an upper clay-rich drape. Analyses of beds from ancient mud-rich outer-shelf and basinal successions (Cleveland Ironstone, Jurassic, UK, and Mowry Shale, Cretaceous, United States) show that they too contain beds with this three-part organization, suggesting that such flows were active in these ancient settings too. Recognition of these microstructures in these ancient mud-dominated successions demonstrates that sediment in these settings was commonly reworked and transported advectively downslope by high-energy events, contrasting with previous interpretations of these units that deposition was dominated by quiescent suspension settling. Identification of these recognition criteria now allows the products of this newly recognized sediment dispersal mechanism to be identified in other shale-dominated successions.
ISSN:0091-7613
1943-2682
DOI:10.1130/G31093.1