The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Yvonne T. Spychala
  • Joris T. Eggenhuisen
  • Mike Tilston
  • Florian Pohl

Organisationseinheiten

Externe Organisationen

  • Utrecht University
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Details

OriginalspracheEnglisch
Seiten (von - bis)3471-3491
Seitenumfang21
FachzeitschriftSEDIMENTOLOGY
Jahrgang67
Ausgabenummer7
Frühes Online-Datum26 Apr. 2020
PublikationsstatusVeröffentlicht - 20 Nov. 2020

Abstract

Submarine lobes have been identified within various deep-water settings, including the basin-floor, the base of slope and the continental slope. Their dimensions and geometries are postulated to be controlled by the topographic configuration of the seabed, sediment supply system and slope gradient. Ten experiments were conducted in a three-dimensional-flume to study the depositional characteristics of submarine lobes associated with: (i) different basin floor gradients (0 to 4°); (ii) different sediment concentrations of the parent turbidity current (11 to 19% vol); and (iii) varying discharge (25 to 40 m 3 h −1). Most runs produced lobate deposits that onlapped onto the lower slope. Deposit length was proportional to basin-floor angle and sediment volume concentration. A higher amount of bypass is observed in the proximal area as the basin-floor angles get steeper and sediment concentrations higher. Deposits of runs with lower discharge could be traced higher upslope while runs with higher discharge produced an area of low deposition behind the channel mouth, i.e. discharge controlled whether lobe deposits were attached or detached from their channel-levée systems. A particle-advection-length scale analysis suggests that this approach can be used as a first order estimation of lobe element length. However, the estimations strongly depend on the average grain size used for calculations (for example, silt is still actively transported after all sand has been deposited) and the method cannot be used to locate the main depocentre. Furthermore, attempted reconstructions of turbidity current velocities from natural systems suggest that the method is not appropriate for use in inversions from more complex composite bodies such as lobes.

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The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements. / Spychala, Yvonne T.; Eggenhuisen, Joris T.; Tilston, Mike et al.
in: SEDIMENTOLOGY, Jahrgang 67, Nr. 7, 20.11.2020, S. 3471-3491.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Spychala YT, Eggenhuisen JT, Tilston M, Pohl F. The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements. SEDIMENTOLOGY. 2020 Nov 20;67(7):3471-3491. Epub 2020 Apr 26. doi: 10.1111/sed.12751
Spychala, Yvonne T. ; Eggenhuisen, Joris T. ; Tilston, Mike et al. / The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements. in: SEDIMENTOLOGY. 2020 ; Jahrgang 67, Nr. 7. S. 3471-3491.
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title = "The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements",
abstract = "Submarine lobes have been identified within various deep-water settings, including the basin-floor, the base of slope and the continental slope. Their dimensions and geometries are postulated to be controlled by the topographic configuration of the seabed, sediment supply system and slope gradient. Ten experiments were conducted in a three-dimensional-flume to study the depositional characteristics of submarine lobes associated with: (i) different basin floor gradients (0 to 4°); (ii) different sediment concentrations of the parent turbidity current (11 to 19% vol); and (iii) varying discharge (25 to 40 m 3 h −1). Most runs produced lobate deposits that onlapped onto the lower slope. Deposit length was proportional to basin-floor angle and sediment volume concentration. A higher amount of bypass is observed in the proximal area as the basin-floor angles get steeper and sediment concentrations higher. Deposits of runs with lower discharge could be traced higher upslope while runs with higher discharge produced an area of low deposition behind the channel mouth, i.e. discharge controlled whether lobe deposits were attached or detached from their channel-lev{\'e}e systems. A particle-advection-length scale analysis suggests that this approach can be used as a first order estimation of lobe element length. However, the estimations strongly depend on the average grain size used for calculations (for example, silt is still actively transported after all sand has been deposited) and the method cannot be used to locate the main depocentre. Furthermore, attempted reconstructions of turbidity current velocities from natural systems suggest that the method is not appropriate for use in inversions from more complex composite bodies such as lobes. ",
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Download

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T1 - The influence of basin setting and turbidity current properties on the dimensions of submarine lobe elements

AU - Spychala, Yvonne T.

AU - Eggenhuisen, Joris T.

AU - Tilston, Mike

AU - Pohl, Florian

N1 - Funding Information: This project was funded by NWO (grant #NWO-ALW-Vidi-864.13.006), ExxonMobil, Shell and Equinor for which we are thankful. Thony van der Gon-Netscher and Han de Witte supplied technical support to the experimental work. Reviews by Sedimentology Associate Editor Kyle Straub and reviewer Elisabeth Steel greatly improved the manuscript. Open access funding enabled and organized by Projekt DEAL.

PY - 2020/11/20

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N2 - Submarine lobes have been identified within various deep-water settings, including the basin-floor, the base of slope and the continental slope. Their dimensions and geometries are postulated to be controlled by the topographic configuration of the seabed, sediment supply system and slope gradient. Ten experiments were conducted in a three-dimensional-flume to study the depositional characteristics of submarine lobes associated with: (i) different basin floor gradients (0 to 4°); (ii) different sediment concentrations of the parent turbidity current (11 to 19% vol); and (iii) varying discharge (25 to 40 m 3 h −1). Most runs produced lobate deposits that onlapped onto the lower slope. Deposit length was proportional to basin-floor angle and sediment volume concentration. A higher amount of bypass is observed in the proximal area as the basin-floor angles get steeper and sediment concentrations higher. Deposits of runs with lower discharge could be traced higher upslope while runs with higher discharge produced an area of low deposition behind the channel mouth, i.e. discharge controlled whether lobe deposits were attached or detached from their channel-levée systems. A particle-advection-length scale analysis suggests that this approach can be used as a first order estimation of lobe element length. However, the estimations strongly depend on the average grain size used for calculations (for example, silt is still actively transported after all sand has been deposited) and the method cannot be used to locate the main depocentre. Furthermore, attempted reconstructions of turbidity current velocities from natural systems suggest that the method is not appropriate for use in inversions from more complex composite bodies such as lobes.

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KW - Advection length

KW - dimensions

KW - experimental study

KW - morphology

KW - sand bias

KW - turbidity current

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U2 - 10.1111/sed.12751

DO - 10.1111/sed.12751

M3 - Article

VL - 67

SP - 3471

EP - 3491

JO - SEDIMENTOLOGY

JF - SEDIMENTOLOGY

SN - 0037-0746

IS - 7

ER -