Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight.

Research output: Contribution to journalJournal articleResearchpeer-review

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Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight. / Anderskouv, Kresten; Surlyk, Finn; Huuse, Mads; Lykke-Andersen, Holger; Bjerager, Morten Gustav Erik; Tang, Cecilie Dybbroe.

In: Marine Geology, Vol. 278, 2010, p. 122-139.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Anderskouv, K, Surlyk, F, Huuse, M, Lykke-Andersen, H, Bjerager, MGE & Tang, CD 2010, 'Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight.', Marine Geology, vol. 278, pp. 122-139. https://doi.org/10.1016/j.margeo.2010.09.009

APA

Anderskouv, K., Surlyk, F., Huuse, M., Lykke-Andersen, H., Bjerager, M. G. E., & Tang, C. D. (2010). Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight. Marine Geology, 278, 122-139. https://doi.org/10.1016/j.margeo.2010.09.009

Vancouver

Anderskouv K, Surlyk F, Huuse M, Lykke-Andersen H, Bjerager MGE, Tang CD. Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight. Marine Geology. 2010;278:122-139. https://doi.org/10.1016/j.margeo.2010.09.009

Author

Anderskouv, Kresten ; Surlyk, Finn ; Huuse, Mads ; Lykke-Andersen, Holger ; Bjerager, Morten Gustav Erik ; Tang, Cecilie Dybbroe. / Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight. In: Marine Geology. 2010 ; Vol. 278. pp. 122-139.

Bibtex

@article{d50e6bf3fd0946a196014f93dcc5498c,
title = "Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight.",
abstract = "Sediment waves composed of fine-grained carbonate ooze with in-place bryozoans are a characteristic element of the Pleistocene of the Great Australian Bight (GAB). The low-amplitude and strongly elongate sediment waves are up to 10 km long, 1 km wide, 40 m high, and oriented sub-parallel to contours immediately off the shelf–slope break. They are asymmetrical, showing up-slope migration, and mainly occur in trains. The sediment waves were drilled during ODP leg 182 in 1998, and were interpreted as biogenic reef mounds. New high-quality seismic and multibeam bathymetry data were acquired on the Galathea 3 expedition in 2006, allowing description of the morphology and internal architecture of the sediment waves in unprecedented detail, leading to an alternative interpretation of their formation. Most sediment waves were initiated by preferential deposition on the landward side of irregular erosion surfaces. Sediment wave accretion took place under the influence of density driven currents, which decelerated up the landward-dipping flanks and accelerated down the seaward-dipping flanks of the sediment waves. The currents are interpreted as dense water cascades formed by summer evaporation and strong winter cooling by analogy with oceanographic processes in the present day GAB. The lithological composition varied with climate and sea level, but sediment wave formation did not. Sediment waves formed and accreted during both glacials and interglacials in contrast to the previous interpretations, which involved growth in glacial periods only. Bryozoans influenced the depositional environment by adding sediment, trapping fine-grained particles, and stabilizing the muddy sea floor. This caused the sediment waves to gain a more prominent sea floor relief than most muddy siliciclastic sediment waves formed by similar depositional processes. The interpretation of the sediment waves as purely biogenic build-ups is rejected, and the sediment waves are most appropriately described as biogenically-influenced sediment waves. ",
author = "Kresten Anderskouv and Finn Surlyk and Mads Huuse and Holger Lykke-Andersen and Bjerager, {Morten Gustav Erik} and Tang, {Cecilie Dybbroe}",
year = "2010",
doi = "10.1016/j.margeo.2010.09.009",
language = "English",
volume = "278",
pages = "122--139",
journal = "Marine Geology",
issn = "0025-3227",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Sediment waves with a biogenic twist in Pleistocene cool water carbonates, Great Australian Bight.

AU - Anderskouv, Kresten

AU - Surlyk, Finn

AU - Huuse, Mads

AU - Lykke-Andersen, Holger

AU - Bjerager, Morten Gustav Erik

AU - Tang, Cecilie Dybbroe

PY - 2010

Y1 - 2010

N2 - Sediment waves composed of fine-grained carbonate ooze with in-place bryozoans are a characteristic element of the Pleistocene of the Great Australian Bight (GAB). The low-amplitude and strongly elongate sediment waves are up to 10 km long, 1 km wide, 40 m high, and oriented sub-parallel to contours immediately off the shelf–slope break. They are asymmetrical, showing up-slope migration, and mainly occur in trains. The sediment waves were drilled during ODP leg 182 in 1998, and were interpreted as biogenic reef mounds. New high-quality seismic and multibeam bathymetry data were acquired on the Galathea 3 expedition in 2006, allowing description of the morphology and internal architecture of the sediment waves in unprecedented detail, leading to an alternative interpretation of their formation. Most sediment waves were initiated by preferential deposition on the landward side of irregular erosion surfaces. Sediment wave accretion took place under the influence of density driven currents, which decelerated up the landward-dipping flanks and accelerated down the seaward-dipping flanks of the sediment waves. The currents are interpreted as dense water cascades formed by summer evaporation and strong winter cooling by analogy with oceanographic processes in the present day GAB. The lithological composition varied with climate and sea level, but sediment wave formation did not. Sediment waves formed and accreted during both glacials and interglacials in contrast to the previous interpretations, which involved growth in glacial periods only. Bryozoans influenced the depositional environment by adding sediment, trapping fine-grained particles, and stabilizing the muddy sea floor. This caused the sediment waves to gain a more prominent sea floor relief than most muddy siliciclastic sediment waves formed by similar depositional processes. The interpretation of the sediment waves as purely biogenic build-ups is rejected, and the sediment waves are most appropriately described as biogenically-influenced sediment waves.

AB - Sediment waves composed of fine-grained carbonate ooze with in-place bryozoans are a characteristic element of the Pleistocene of the Great Australian Bight (GAB). The low-amplitude and strongly elongate sediment waves are up to 10 km long, 1 km wide, 40 m high, and oriented sub-parallel to contours immediately off the shelf–slope break. They are asymmetrical, showing up-slope migration, and mainly occur in trains. The sediment waves were drilled during ODP leg 182 in 1998, and were interpreted as biogenic reef mounds. New high-quality seismic and multibeam bathymetry data were acquired on the Galathea 3 expedition in 2006, allowing description of the morphology and internal architecture of the sediment waves in unprecedented detail, leading to an alternative interpretation of their formation. Most sediment waves were initiated by preferential deposition on the landward side of irregular erosion surfaces. Sediment wave accretion took place under the influence of density driven currents, which decelerated up the landward-dipping flanks and accelerated down the seaward-dipping flanks of the sediment waves. The currents are interpreted as dense water cascades formed by summer evaporation and strong winter cooling by analogy with oceanographic processes in the present day GAB. The lithological composition varied with climate and sea level, but sediment wave formation did not. Sediment waves formed and accreted during both glacials and interglacials in contrast to the previous interpretations, which involved growth in glacial periods only. Bryozoans influenced the depositional environment by adding sediment, trapping fine-grained particles, and stabilizing the muddy sea floor. This caused the sediment waves to gain a more prominent sea floor relief than most muddy siliciclastic sediment waves formed by similar depositional processes. The interpretation of the sediment waves as purely biogenic build-ups is rejected, and the sediment waves are most appropriately described as biogenically-influenced sediment waves.

U2 - 10.1016/j.margeo.2010.09.009

DO - 10.1016/j.margeo.2010.09.009

M3 - Journal article

VL - 278

SP - 122

EP - 139

JO - Marine Geology

JF - Marine Geology

SN - 0025-3227

ER -

ID: 32441949