Sedimentologic and stratigraphic criteria to distinguish between basin‐floor and slope mudstones: Implications for the delivery of mud to deep‐water environments

Deep‐water mudstones overlying basin‐floor and slope sandstone‐prone deposits are often interpreted as hemipelagic drapes deposited during sand starvation periods. However, mud transport and depositional processes, and resulting facies and architecture of mudstones in deep‐water environments, remain poorly understood. This study documents the sedimentology and stratigraphy of basin‐floor and slope mudstones intercalated with sandstone‐prone deposits of the Laingsburg depocentre (Karoo Basin, South Africa). Sedimentologic and stratigraphic criteria are presented here to distinguish between slope and basin‐floor mudstones, which provide a tool to refine palaeogeographical reconstructions of other deep‐water successions. Several mudstone units were mapped at outcrop for 2500 km2 and investigated using macroscopic and microscopic core descriptions from two research boreholes. Basin‐floor mudstones exhibit a repeated and predictable alternation of bedsets dominated by low‐density turbidites, and massive packages dominated by debrites, with evidence of turbulent‐to‐laminar flow transformations. Slope mudstones exhibit a similar facies assemblage, but the proportion of low‐density turbidites is higher, and no repeated or predictable facies organisation is recognised. The well‐ordered and predictable facies organisation of basin‐floor mudstones suggest local point sources from active slope conduits, responsible for deposition of compensationally stacked muddy lobes. The lack of predictable facies organisation in slope mudstones suggests deposition took place in a more variable range of sub‐environments (i.e. ponded accommodation, minor gully/channel‐fills, levees). However, regional mapping of three mudstone units evidence basinward tapering and similar thicknesses across depositional strike. This geometry is consistent with the distal part of basin margin clinothems, and suggests laterally extensive mud delivery across the shelf edge combined with along‐margin transport processes. Therefore, the sedimentology and geometry of mudstones suggests that mud can be delivered to deep‐water dominantly by sediment gravity flows through point source and distributed regionally, during periods of up‐dip sand storage. These findings challenge the common attribution of deep‐water mudstones to periods of basin‐floor sediment starvation.

[1]  D. Hodgson,et al.  Lateral variability of shelf-edge and basin-floor deposits, Santos Basin, offshore Brazil , 2020, Journal of Sedimentary Research.

[2]  J. Baas,et al.  Mixed sand–mud bedforms produced by transient turbulent flows in the fringe of submarine fans: Indicators of flow transformation , 2020, Sedimentology.

[3]  M. L. Sweet,et al.  Sediment routing from shelf to basin floor in the Quaternary Golo System of Eastern Corsica, France, western Mediterranean Sea , 2019, GSA Bulletin.

[4]  S. Davies,et al.  From marine bands to hybrid flows: Sedimentology of a Mississippian black shale , 2019, Sedimentology.

[5]  V. Paumard CONTROLS ON DEEP-WATER SAND DELIVERY BEYOND THE SHELF EDGE: ACCOMMODATION, SEDIMENT SUPPLY AND DELTAIC PROCESS REGIME , 2019 .

[6]  K. Taylor,et al.  Fringe or background: Characterizing deep-water mudstones beyond the basin-floor fan sandstone pinchout , 2019, Journal of Sedimentary Research.

[7]  K. Taylor,et al.  Transport and deposition of mud in deep‐water environments: Processes and stratigraphic implications , 2019, Sedimentology.

[8]  D. Hodgson,et al.  Clinoform architecture and along‐strike facies variability through an exhumed erosional to accretionary basin margin transition , 2019, Basin Research.

[9]  F. Hernández‐Molina,et al.  Contourite depositional systems along the Mozambique channel: The interplay between bottom currents and sedimentary processes , 2019, Deep Sea Research Part I: Oceanographic Research Papers.

[10]  J. Peakall,et al.  Deep-water channel-lobe transition zone dynamics: Processes and depositional architecture, an example from the Karoo Basin, South Africa , 2018 .

[11]  D. Hodgson,et al.  Filter Or Conveyor? Establishing Relationships Between Clinoform Rollover Trajectory, Sedimentary Process Regime, and Grain Character Within Intrashelf Clinothems, Offshore New Jersey, U.S.A. , 2018, Journal of Sedimentary Research.

[12]  J. Peakall,et al.  Disconnected submarine lobes as a record of stepped slope evolution over multiple sea-level cycles , 2018, Geosphere.

[13]  R. Dorrell,et al.  Pulse propagation in turbidity currents , 2018 .

[14]  E. Hough,et al.  Sedimentology and microfacies of a mud-rich slope succession: in the Carboniferous Bowland Basin, NW England (UK) , 2017, Journal of the Geological Society.

[15]  J. Eggenhuisen,et al.  The stratigraphic record and processes of turbidity current transformation across deep‐marine lobes , 2017 .

[16]  Z. Sylvester,et al.  Sediment partitioning, continental slopes and base‐of‐slope systems , 2017 .

[17]  D. Hodgson,et al.  Aggradational lobe fringes: The influence of subtle intrabasinal seabed topography on sediment gravity flow processes and lobe stacking patterns , 2017 .

[18]  S. Luthi,et al.  Integrating outcrop and subsurface data to assess the temporal evolution of a submarine channel–levee system , 2016 .

[19]  P. Plink-Björklund,et al.  Defining the shelf edge and the three‐dimensional shelf edge to slope facies variability in shelf‐edge deltas , 2016 .

[20]  F. Felletti,et al.  Hybrid Event Beds Generated By Local Substrate Delamination On A Confined-Basin Floor , 2016 .

[21]  D. Hodgson,et al.  Mud-Dominated Basin-Margin Progradation: Processes and Implications , 2016 .

[22]  Yingmin Wang,et al.  Grain size and transport regime at shelf edge as fundamental controls on delivery of shelf-edge sands to deepwater , 2016 .

[23]  J. Rocheleau,et al.  Stratal composition and stratigraphic organization of stratal elements in an ancient deep‐marine basin‐floor succession, Neoproterozoic Windermere Supergroup, British Columbia, Canada , 2016 .

[24]  D. Hodgson,et al.  Lateral variability in clinoform trajectory, process regime, and sediment dispersal patterns beyond the shelf‐edge rollover in exhumed basin margin‐scale clinothems , 2015 .

[25]  F. Felletti,et al.  Short length-scale variability of hybrid event beds and its applied significance , 2015 .

[26]  Pierre Testor,et al.  Glider monitoring of shelf suspended particle dynamics and transport during storm and flooding conditions , 2015 .

[27]  J. Eggenhuisen,et al.  Deep-Water Sediment Bypass , 2015 .

[28]  K. Pickering,et al.  Deep-marine environments of the Middle Eocene Upper Hecho Group, Spanish Pyrenees: Introduction , 2015 .

[29]  J. Macquaker,et al.  Capturing Key Attributes of Fine-Grained Sedimentary Rocks In Outcrops, Cores, and Thin Sections: Nomenclature and Description Guidelines , 2015 .

[30]  D. Hodgson,et al.  Depositional architecture of sand-attached and sand-detached channel-lobe transition zones on an exhumed stepped slope mapped over a 2500 km2 area , 2014 .

[31]  R. Ainsworth,et al.  Seismic stratigraphy and geomorphology of a tide or wave dominated shelf-edge delta (NW Australia): Process-based classification from 3D seismic attributes and implications for the prediction of deep-water sands , 2014 .

[32]  D. Hodgson,et al.  Origin, evolution and anatomy of silt‐prone submarine external levées , 2014 .

[33]  P. Butterworth,et al.  Sedimentology, Stratigraphic Architecture, and Depositional Context of Submarine Frontal-Lobe Complexes , 2014 .

[34]  J. Clark,et al.  Ichnofabric characterization of a deep‐marine clastic system: a subsurface study of the Middle Eocene Ainsa System, Spanish Pyrenees , 2014 .

[35]  P. Haughton,et al.  Rheological Complexity In Sediment Gravity Flows Forced To Decelerate Against A Confining Slope, Braux, SE France , 2014 .

[36]  A. Plint Mud dispersal across a Cretaceous prodelta: Storm‐generated, wave‐enhanced sediment gravity flows inferred from mudstone microtexture and microfacies , 2014 .

[37]  Melanie J. Leng,et al.  Depositional Controls On Mudstone Lithofacies In A Basinal Setting: Implications for the Delivery of Sedimentary Organic Matter , 2014 .

[38]  S. Grundvåg,et al.  Depositional architecture and evolution of progradationally stacked lobe complexes in the Eocene Central Basin of Spitsbergen , 2014 .

[39]  D. Hodgson,et al.  Driving a channel through a levee when the levee is high: An outcrop example of submarine down-dip entrenchment , 2013 .

[40]  J. Pringle,et al.  Confined to unconfined: Anatomy of a base of slope succession, Karoo Basin, South Africa , 2013 .

[41]  D. Hodgson,et al.  The full range of turbidite bed thickness patterns in submarine lobes: controls and implications , 2013, Journal of the Geological Society.

[42]  Esther J. Sumner,et al.  Subaqueous sediment density flows: Depositional processes and deposit types , 2012 .

[43]  I. Kane,et al.  Submarine transitional flow deposits in the Paleogene Gulf of Mexico , 2012 .

[44]  R. Steel,et al.  River‐dominated, shelf‐edge deltas: delivery of sand across the shelf break in the absence of slope incision , 2012 .

[45]  D. Lowe,et al.  Climbing‐ripple successions in turbidite systems: depositional environments, sedimentation rates and accumulation times , 2012 .

[46]  H. Veld,et al.  Toarcian Black Shales In the Dutch Central Graben: Record of Energetic, Variable Depositional Conditions During An Oceanic Anoxic Event , 2012 .

[47]  J. Best,et al.  Depositional processes, bedform development and hybrid bed formation in rapidly decelerated cohesive (mud–sand) sediment flows , 2011 .

[48]  D. Hodgson,et al.  Spatial and Temporal Evolution of a Permian Submarine Slope Channel–Levee System, Karoo Basin, South Africa , 2011 .

[49]  Roeland van Gilst,et al.  The sedimentary expression of oceanic anoxic event 1b in the North Atlantic , 2011 .

[50]  J. A. Maceachern,et al.  Process ichnology and the elucidation of physico-chemical stress , 2011 .

[51]  D. Hodgson,et al.  Submarine slope degradation and aggradation and the stratigraphic evolution of channel–levee systems , 2011, Journal of the Geological Society.

[52]  D. Hodgson,et al.  Sedimentological criteria to differentiate submarine channel levee subenvironments: Exhumed examples from the Rosario Fm. (Upper Cretaceous) of Baja California, Mexico, and the Fort Brown Fm. (Permian), Karoo Basin, S. Africa , 2011 .

[53]  D. Box,et al.  Depositional architecture and sequence stratigraphy of the Karoo basin floor to shelf edge succession, Laingsburg depocentre, South Africa , 2011 .

[54]  D. Hodgson,et al.  Sequence stratigraphy of an argillaceous, deepwater basin-plain succession: Vischkuil Formation (Permian), Karoo Basin, South Africa , 2010 .

[55]  D. Hodgson,et al.  Evolution, architecture and hierarchy of distributary deep‐water deposits: a high‐resolution outcrop investigation from the Permian Karoo Basin, South Africa , 2009 .

[56]  R. Higgs Multiscale stratigraphic analysis of a structurally confined submarine fan: Carboniferous Ross Sandstone, Ireland: Discussion , 2009 .

[57]  D. Hodgson Distribution and origin of hybrid beds in sand-rich submarine fans of the Tanqua depocentre, Karoo Basin, South Africa , 2009 .

[58]  R. Steel,et al.  Shelf-Edge Architecture and Bypass of Sand to Deep Water: Influence of Shelf-Edge Processes, Sea Level, and Sediment Supply , 2009 .

[59]  R. Newton,et al.  Tectonic evolution of the Cape and Karoo basins of South Africa , 2009 .

[60]  D. Hodgson,et al.  Widespread syn‐sedimentary deformation on a muddy deep‐water basin‐floor: the Vischkuil Formation (Permian), Karoo Basin, South Africa , 2009 .

[61]  D. Pyles Multiscale stratigraphic analysis of a structurally confined submarine fan: Carboniferous Ross Sandstone, Ireland , 2008 .

[62]  Thomas G. Heard,et al.  Trace fossils as diagnostic indicators of deep‐marine environments, Middle Eocene Ainsa‐Jaca basin, Spanish Pyrenees , 2007 .

[63]  B. Romans,et al.  Highstand fans in the California borderland: The overlooked deep-water depositional systems , 2007 .

[64]  Stephen C. Ruppel,et al.  Mississippian Barnett Shale: Lithofacies and depositional setting of a deep-water shale-gas succession in the Fort Worth Basin, Texas , 2007 .

[65]  Rob L. Gawthorpe,et al.  High-Resolution Facies Analyses of Mudstones: Implications for Paleoenvironmental and Sequence Stratigraphic Interpretations of Offshore Ancient Mud-Dominated Successions , 2007 .

[66]  X. D. D. Madron,et al.  Suspended sediment fluxes and transport processes in the Gulf of Lions submarine canyons. The role of storms and dense water cascading , 2006 .

[67]  T. Mulder,et al.  Sandy modern turbidite lobes: A new insight from high resolution seismic data , 2006 .

[68]  R. Steel,et al.  Shelf‐margin clinoforms and prediction of deepwater sands , 2005 .

[69]  R. Beaubouef,et al.  Deep-water leveed-channel complexes of the Cerro Toro Formation, Upper Cretaceous, southern Chile , 2004 .

[70]  J. Melick,et al.  Stratigraphic process-response model for submarine channels and related features from studies of Permian Brushy Canyon outcrops, West Texas [Marine and Petroleum Geology 20 (6–8) (2003) 757–787] , 2004 .

[71]  S. Flint,et al.  Anatomy and Stratigraphic Development of a Basin Floor Turbidite System in the Laingsburg Formation, Main Karoo Basin, South Africa , 2004 .

[72]  R. Wynn,et al.  Beds comprising debrite sandwiched within co‐genetic turbidite: origin and widespread occurrence in distal depositional environments , 2004 .

[73]  S. Flint,et al.  Upward‐thickening patterns and lateral continuity of Permian sand‐rich turbidite channel fills, Laingsburg Karoo, South Africa , 2003 .

[74]  R. Steel,et al.  Shelf-margin deltas: their stratigraphic significance and relation to deepwater sands , 2003 .

[75]  B. Kneller,et al.  The Interpretation of Vertical Sequences in Turbidite Beds: The Influence of Longitudinal Flow Structure , 2003 .

[76]  G. Potts,et al.  Partial Ponding of Turbidite Systems in a Basin with Subtle Growth-Fold Topography: Laingsburg-Karoo, South Africa , 2003 .

[77]  P. Haughton,et al.  ‘Linked’ debrites in sand‐rich turbidite systems – origin and significance , 2003 .

[78]  J. Melick,et al.  Stratigraphic process-response model for submarine channels and related features from studies of Permian Brushy Canyon outcrops, West Texas , 2003 .

[79]  Sébastien Migeon,et al.  Marine hyperpycnal flows: initiation, behavior and related deposits. A review , 2003 .

[80]  Henry W. Posamentier,et al.  Seismic Geomorphology and Stratigraphy of Depositional Elements in Deep-Water Settings , 2003 .

[81]  Charles A. Nittrouer,et al.  Shelf-to-canyon sediment-transport processes on the Eel continental margin (northern California) , 2003 .

[82]  H. Sinclair,et al.  Depositional Evolution of Confined Turbidite Basins , 2002 .

[83]  J. Best,et al.  Turbulence Modulation in Clay-Rich Sediment-Laden Flows and Some Implications for Sediment Deposition , 2002 .

[84]  R. Steel,et al.  Sea-level fall below the shelf edge, without basin-floor fans , 2002 .

[85]  Carl T. Friedrichs,et al.  Effects of ambient currents and waves on gravity-driven sediment transport on continental shelves , 2001 .

[86]  J. Alexander,et al.  The physical character of subaqueous sedimentary density flows and their deposits , 2001 .

[87]  A. Uchman,et al.  Sequential colonization of muddy turbidites in the Eocene Beloveža Formation, Carpathians, Poland , 2001 .

[88]  S. J. Friedmann,et al.  High Resolution Seismic/Sequence Stratigraphic Framework for the Evolution of Pleistocene Intra Slope Basins, Western Gulf of Mexico: Depositional Models and Reservoir Analogs , 2000 .

[89]  J. Lynch,et al.  The role of wave-induced density-driven fluid mud flows for cross-shelf transport on the Eel River continental shelf , 2000 .

[90]  D. Cacchione,et al.  Observations of storm and river flood-driven sediment transport on the northern California continental shelf , 2000 .

[91]  R. Wynn,et al.  The Northwest African slope apron: a modern analogue for deep-water systems with complex seafloor topography , 2000 .

[92]  J. Schieber Distribution and deposition of mudstone facies in the Upper Devonian Sonyea Group of New York , 1999 .

[93]  J. Mitrovica,et al.  The Role of Subduction‐Induced Subsidence in the Evolution of the Karoo Basin , 1999, The Journal of Geology.

[94]  J. Walsh,et al.  Observations of sediment flux to the Eel continental slope, northern California , 1999 .

[95]  N. Driscoll,et al.  Three-dimensional quantitative modeling of clinoform development , 1999 .

[96]  Catuneanu,et al.  Reciprocal flexural behaviour and contrasting stratigraphies: a new basin development model for the Karoo retroarc foreland system, South Africa , 1998 .

[97]  L. Pratson,et al.  Clinoform development by advection-diffusion of suspended sediment: Modeling and comparison to natural systems , 1998 .

[98]  R. Iverson,et al.  U. S. Geological Survey , 1967, Radiocarbon.

[99]  J. Visser,et al.  Subduction, mega-shear systems and Late Palaeozoic basin development in the African segment of Gondwana , 1996 .

[100]  M. R. Johnson,et al.  Stratigraphy of the Karoo Supergroup in southern Africa: an overview , 1996 .

[101]  Matthew R. Bennett,et al.  Dropstones: their origin and significance , 1996 .

[102]  Michael J. Branney,et al.  Sustained high‐density turbidity currents and the deposition of thick massive sands , 1995 .

[103]  D. Cacchione,et al.  Measurements in the bottom boundary layer on the Amazon subaqueous delta , 1995 .

[104]  I. N. McCave,et al.  Sortable silt and fine sediment size/composition slicing: Parameters for palaeocurrent speed and palaeoceanography , 1995 .

[105]  J. Syvitski,et al.  Turbidity Currents Generated at River Mouths during Exceptional Discharges to the World Oceans , 1995, The Journal of Geology.

[106]  A. Tankard,et al.  Inversion tectonics of the Cape Fold Belt, Karoo and Cretaceous basins of Southern Africa , 1995 .

[107]  J. Schieber Evidence for high-energy events and shallow-water deposition in the Chattanooga Shale, Devonian, central Tennessee, USA , 1994 .

[108]  J. Macquaker,et al.  Mudstone Lithofacies in the Kimmeridge Clay Formation, Wessex Basin, Southern England: Implications for the Origin and Controls of the Distribution of Mudstones , 1994 .

[109]  J. Viljoen Sedimentology of the Collingham Formation, Karoo Supergroup , 1994 .

[110]  M. Richards,et al.  Turbidite Systems in Deep-Water Basin Margins Classified by Grain Size and Feeder System , 1994 .

[111]  R. Goldring,et al.  Description and analysis of bioturbation and ichnofabric , 1993, Journal of the Geological Society.

[112]  J. Visser Deposition of the Early to Late Permian Whitehill formation during a sea-level highstand in a juvenile foreland basin , 1992 .

[113]  J. Best,et al.  The morphology and dynamics of low amplitude bedwaves upon upper stage plane beds and the preservation of planar laminae , 1992 .

[114]  B. Hand,et al.  Bedforms, primary structures and grain fabric in the presence of suspended sediment rain , 1989 .

[115]  F. Surlyk Slope and Deep Shelf Gully Sandstones, Upper Jurassic, East Greenland , 1987 .

[116]  D. DeMaster,et al.  The deltaic nature of Amazon shelf sedimentation , 1986 .

[117]  P. Heller,et al.  Submarine ramp facies model for delta-fed, sand-rich turbidite systems , 1985 .

[118]  C. Finkl Sedimentary structures — their character and physical basis , 1983 .

[119]  D. Lowe Sediment Gravity Flows: II Depositional Models with Special Reference to the Deposits of High-Density Turbidity Currents , 1982 .

[120]  J. M. Coleman,et al.  Physical Processes and Fine-grained Sediment Dynamics, Coast of Surinam, South America , 1981 .

[121]  C. Summerhayes Organic Facies of Middle Cretaceous Black Shales in Deep North Atlantic , 1981 .

[122]  A. Bowen,et al.  Sediment waves on the monterey fan levee: A preliminary physical interpretation , 1980 .

[123]  P. Masson,et al.  Paleoenvironment and Petroleum Potential of Middle Cretaceous Black Shales in Atlantic Basins , 1980 .

[124]  D. Gorsline Anatomy of margin basins; presidential address , 1978 .

[125]  R. E. Hunter Terminology of cross-stratified sedimentary layers and climbing-ripple structures , 1977 .

[126]  R. Walker,et al.  Morphology and origin of ripple-drift cross-lamination, with examples from the Pleistocene of Massachusetts , 1968 .

[127]  C. V. Campbell Lamina, Laminaset, Bed and Bedset , 1967 .

[128]  K. Emery,et al.  TURBIDITY-CURRENT DEPOSITS IN SAN PEDRO AND SANTA MONICA BASINS OFF SOUTHERN CALIFORNIA , 1959 .

[129]  E. Buffington Submarine "Natural Levees" , 1952, The Journal of Geology.

[130]  D. Phillips,et al.  An Overview of Cape Fold Belt Geochronology: Implications for Sediment Provenance and the Timing of Orogenesis , 2016 .

[131]  E. M. Bordy,et al.  Spatiotemporal Sedimentary Facies Variations in the Lower Permian Whitehill Formation, Ecca Group, Karoo Basin , 2016 .

[132]  J. Macquaker,et al.  Mudstone Primer: Lithofacies variations, diagnostic criteria, and sedimentologic–stratigraphic implications at lamina to bedset scale , 2015 .

[133]  B. Savoye,et al.  Application of the Principles Seismic Geomorphology to Continental Slope and Base-of-slope Systems : Case Studies from Seafloor and Near-Seafloor Analogues , 2012 .

[134]  Z. Sylvester,et al.  Seismic Stratigraphy of a Shelf-Edge Delta and Linked Submarine Channels in the Northeastern Gulf of Mexico , 2012 .

[135]  R. Wynn,et al.  Applications of the Principles of Seismic Geomorphology to Continental-slope and Base-of-slope Systems: Case studies from seafloor and near-seafloor analogues , 2012 .

[136]  R. Newton,et al.  Geodynamic interpretation of the Cape and Karoo basins, South Africa , 2012 .

[137]  John B. Southard,et al.  Lenticular Shale Fabrics Resulting from Intermittent Erosion of Water-Rich Muds—Interpreting the Rock Record in the Light of Recent Flume Experiments , 2010 .

[138]  N. Drinkwater,et al.  Stratigraphic Evolution of Fine-Grained Submarine Fan Systems, Tanqua Depocenter, Karoo Basin, South Africa , 2006 .

[139]  H. Posamentier,et al.  Deep-Water Turbidites and Submarine Fans , 2006 .

[140]  E. Johannessen,et al.  Submarine fan morphology and lithology distribution: a predictable function of sediment delivery, gross shelf-to-basin relief, slope gradient and basin topography , 2005 .

[141]  T. Mulder,et al.  Concept of equilibrium profile in deep-water turbidite system: effects of local physiographic changes on the nature of sedimentary process and the geometries of deposits , 2005, Geological Society, London, Special Publications.

[142]  R. Steel,et al.  Shelf-Edge Delta Types and Their Sequence-Stratigraphic Relationships , 2003 .

[143]  H. Lee,et al.  Origin of Inner-Shelf Mud Deposit in the Southeastern Yellow Sea: Huksan Mud Belt , 2001 .

[144]  R. Sternberg,et al.  Fluid-mud processes on the Amazon continental shelf , 1996 .

[145]  E. Cowan,et al.  Southern Africa: Karoo Basin and Cape Fold Belt , 1994 .

[146]  C. Powell,et al.  Permian-Triassic Pangean Basins and Foldbelts Along the Panthalassan Margin of Gondwanaland , 1994 .

[147]  R.M.H. Smith,et al.  A review of stratigraphy and sedimentary environments of the Karoo Basin of South Africa , 1990 .

[148]  W. Normark,et al.  Comparing Examples of Modern and Ancient Turbidite Systems: Problems and Concepts , 1987 .

[149]  S. Penland,et al.  Late Quaternary Sea-Level Fluctuations and Depositional Sequences, Southwest Louisiana Continental Shelf , 1987 .

[150]  A. Wetzel Bioturbation in deep-sea fine-grained sediments: influence of sediment texture, turbidite frequency and rates of environmental change , 1984, Geological Society, London, Special Publications.

[151]  G. Shanmugam,et al.  Sequence of structures in fine-grained turbidites: Comparison of recent deep-sea and ancient flysch sediments , 1980 .

[152]  F. Hein,et al.  A Review of Mass Movement Processes Sediment and Acoustic Characteristics, and Contrasts in Slope and Base-of-Slope Systems Versus Canyon-Fan-Basin Floor Systems , 1979 .

[153]  D. Stanley,et al.  Sedimentation in submarine canyons, fans and trenches , 1978 .

[154]  D. Gorsline Anatomy of Margin Basins , 1978 .