Physical, biological, geochemical and sedimentological controls on the ichnology of continental slope channel systems

Richard H. T. Callow; Ben Kneller; Mason Dykstra; Duncan McIlroy

doi:10.1016/j.marpetgeo.2014.02.016

Physical, biological, geochemical and sedimentological controls on the ichnology of continental slope channel systems

Richard H. T. Callow, Ben Kneller, Mason Dykstra, Duncan McIlroy

Geology and Geophysics

Research output: Contribution to journal › Article › peer-review

31 Citations (Scopus)

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Abstract

Sediments of the continental slope are commonly bioturbated by endo- and epibenthic organisms, particularly in and around submarine canyons and channels. This study reviews the architecture and depositional environments associated with canyons and channels on the continental slope, and assesses the key physical and chemical conditions encountered in and around these conduits. Hydrodynamic energy, concentration and quality of organic carbon, dissolved oxygen concentration and sedimentation rate are identified as key controls on the composition of benthic ecosystems in slope environments. Submarine canyons and channels focus a variety of turbid and clear-water currents, all of which serve to increase the concentration of oxygen, labile organic carbon and other nutrients, which tend to elevate the abundance and biodiversity in the seafloor sediments, compared with those of the surrounding slope. Ancient slope channel and canyon systems reflect some of the variation in ichnological assemblages that is seen in modern analogues, although processes of erosion and trace fossil preservation mean that the benthic environment is often incompletely preserved in the ancient record. By integrating current understanding of sedimentology, oceanography, biology and ichnology of slope environments it is possible to provide a first order summary of the inter-relationships between ichnology and depositional environments on the continental slope. The combination of these data has the potential to improve our understanding of changes in deep marine benthic ecosystems through geological time, and to further the use of ichnology in assessing hydrocarbon reservoir presence, quality and performance from bioturbated slope, canyon and channel-levee hydrocarbon reservoirs.

Original language	English
Pages (from-to)	144-166
Number of pages	23
Journal	Marine and Petroleum Geology
Volume	54
Early online date	2 Mar 2014
DOIs	https://doi.org/10.1016/j.marpetgeo.2014.02.016
Publication status	Published - Jun 2014

Bibliographical note

RC acknowledges the support of a postdoctoral fellowship from the PRACSS Consortium (funded by BG Group, BP, DONG, RWE Dea, Petrochina, Statoil and Tullow Oil). DMc acknowledges the financial support of a Canada Research Chair and an NSERC Discovery Grant. Our colleagues Bryan Cronin, Fabiano Gamberi, Larissa Hansen, Liam Herringshaw and Christopher Phillips are thanked for their discussions and comments. Elisabeth Kahlmeyer is thanked for assistance with drafting. We are grateful for the helpful advice and constructive feedback from the reviewers Steve Hubbard and David Hodgson, whose suggestions greatly strengthened the manuscript.

Keywords

ichnology
turbidite
slope
canyon
channel
levee
bioturbation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Accepted Manuscript
© 2014. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/
Accepted author manuscript, 3.01 MBLicence: CC BY-NC-ND

Cite this

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title = "Physical, biological, geochemical and sedimentological controls on the ichnology of continental slope channel systems",

abstract = "Sediments of the continental slope are commonly bioturbated by endo- and epibenthic organisms, particularly in and around submarine canyons and channels. This study reviews the architecture and depositional environments associated with canyons and channels on the continental slope, and assesses the key physical and chemical conditions encountered in and around these conduits. Hydrodynamic energy, concentration and quality of organic carbon, dissolved oxygen concentration and sedimentation rate are identified as key controls on the composition of benthic ecosystems in slope environments. Submarine canyons and channels focus a variety of turbid and clear-water currents, all of which serve to increase the concentration of oxygen, labile organic carbon and other nutrients, which tend to elevate the abundance and biodiversity in the seafloor sediments, compared with those of the surrounding slope. Ancient slope channel and canyon systems reflect some of the variation in ichnological assemblages that is seen in modern analogues, although processes of erosion and trace fossil preservation mean that the benthic environment is often incompletely preserved in the ancient record. By integrating current understanding of sedimentology, oceanography, biology and ichnology of slope environments it is possible to provide a first order summary of the inter-relationships between ichnology and depositional environments on the continental slope. The combination of these data has the potential to improve our understanding of changes in deep marine benthic ecosystems through geological time, and to further the use of ichnology in assessing hydrocarbon reservoir presence, quality and performance from bioturbated slope, canyon and channel-levee hydrocarbon reservoirs.",

keywords = "ichnology, turbidite, slope, canyon, channel, levee, bioturbation",

author = "Callow, {Richard H. T.} and Ben Kneller and Mason Dykstra and Duncan McIlroy",

note = "RC acknowledges the support of a postdoctoral fellowship from the PRACSS Consortium (funded by BG Group, BP, DONG, RWE Dea, Petrochina, Statoil and Tullow Oil). DMc acknowledges the financial support of a Canada Research Chair and an NSERC Discovery Grant. Our colleagues Bryan Cronin, Fabiano Gamberi, Larissa Hansen, Liam Herringshaw and Christopher Phillips are thanked for their discussions and comments. Elisabeth Kahlmeyer is thanked for assistance with drafting. We are grateful for the helpful advice and constructive feedback from the reviewers Steve Hubbard and David Hodgson, whose suggestions greatly strengthened the manuscript. ",

year = "2014",

month = jun,

doi = "10.1016/j.marpetgeo.2014.02.016",

language = "English",

volume = "54",

pages = "144--166",

journal = "Marine and Petroleum Geology",

issn = "0264-8172",

publisher = "Elsevier",

}

TY - JOUR

T1 - Physical, biological, geochemical and sedimentological controls on the ichnology of continental slope channel systems

AU - Callow, Richard H. T.

AU - Kneller, Ben

AU - Dykstra, Mason

AU - McIlroy, Duncan

N1 - RC acknowledges the support of a postdoctoral fellowship from the PRACSS Consortium (funded by BG Group, BP, DONG, RWE Dea, Petrochina, Statoil and Tullow Oil). DMc acknowledges the financial support of a Canada Research Chair and an NSERC Discovery Grant. Our colleagues Bryan Cronin, Fabiano Gamberi, Larissa Hansen, Liam Herringshaw and Christopher Phillips are thanked for their discussions and comments. Elisabeth Kahlmeyer is thanked for assistance with drafting. We are grateful for the helpful advice and constructive feedback from the reviewers Steve Hubbard and David Hodgson, whose suggestions greatly strengthened the manuscript.

PY - 2014/6

Y1 - 2014/6

N2 - Sediments of the continental slope are commonly bioturbated by endo- and epibenthic organisms, particularly in and around submarine canyons and channels. This study reviews the architecture and depositional environments associated with canyons and channels on the continental slope, and assesses the key physical and chemical conditions encountered in and around these conduits. Hydrodynamic energy, concentration and quality of organic carbon, dissolved oxygen concentration and sedimentation rate are identified as key controls on the composition of benthic ecosystems in slope environments. Submarine canyons and channels focus a variety of turbid and clear-water currents, all of which serve to increase the concentration of oxygen, labile organic carbon and other nutrients, which tend to elevate the abundance and biodiversity in the seafloor sediments, compared with those of the surrounding slope. Ancient slope channel and canyon systems reflect some of the variation in ichnological assemblages that is seen in modern analogues, although processes of erosion and trace fossil preservation mean that the benthic environment is often incompletely preserved in the ancient record. By integrating current understanding of sedimentology, oceanography, biology and ichnology of slope environments it is possible to provide a first order summary of the inter-relationships between ichnology and depositional environments on the continental slope. The combination of these data has the potential to improve our understanding of changes in deep marine benthic ecosystems through geological time, and to further the use of ichnology in assessing hydrocarbon reservoir presence, quality and performance from bioturbated slope, canyon and channel-levee hydrocarbon reservoirs.

AB - Sediments of the continental slope are commonly bioturbated by endo- and epibenthic organisms, particularly in and around submarine canyons and channels. This study reviews the architecture and depositional environments associated with canyons and channels on the continental slope, and assesses the key physical and chemical conditions encountered in and around these conduits. Hydrodynamic energy, concentration and quality of organic carbon, dissolved oxygen concentration and sedimentation rate are identified as key controls on the composition of benthic ecosystems in slope environments. Submarine canyons and channels focus a variety of turbid and clear-water currents, all of which serve to increase the concentration of oxygen, labile organic carbon and other nutrients, which tend to elevate the abundance and biodiversity in the seafloor sediments, compared with those of the surrounding slope. Ancient slope channel and canyon systems reflect some of the variation in ichnological assemblages that is seen in modern analogues, although processes of erosion and trace fossil preservation mean that the benthic environment is often incompletely preserved in the ancient record. By integrating current understanding of sedimentology, oceanography, biology and ichnology of slope environments it is possible to provide a first order summary of the inter-relationships between ichnology and depositional environments on the continental slope. The combination of these data has the potential to improve our understanding of changes in deep marine benthic ecosystems through geological time, and to further the use of ichnology in assessing hydrocarbon reservoir presence, quality and performance from bioturbated slope, canyon and channel-levee hydrocarbon reservoirs.

KW - ichnology

KW - turbidite

KW - slope

KW - canyon

KW - channel

KW - levee

KW - bioturbation

U2 - 10.1016/j.marpetgeo.2014.02.016

DO - 10.1016/j.marpetgeo.2014.02.016

M3 - Article

SN - 0264-8172

VL - 54

SP - 144

EP - 166

JO - Marine and Petroleum Geology

JF - Marine and Petroleum Geology

ER -

Physical, biological, geochemical and sedimentological controls on the ichnology of continental slope channel systems

Abstract

Bibliographical note

Keywords

UN SDGs

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