Your search keyword '"Jorry, Stephan J."' showing total 5 results

1. Sedimentology and distribution of late quaternary calciturbidites and calcidebrites in the Mozambique Channel (Southwest Indian Ocean)

Author

Counts, John W., Jorry, Stephan J., Vazquez-Riveiros, Natalia, Amy, Lawrence A., Dennielou, Ewen, and Jouet, Gwenael

Published

2021

2. Intermediate and deep ocean current circulation in the Mozambique Channel: New insights from ferromanganese crust Nd isotopes

Author

Charles, Claire, Pelleter, Ewan, Révillon, Sidonie, Nonnotte, Philippe, Jorry, Stephan J., Kluska, Jean-Michel, Domaines Océaniques (LDO), and Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Observatoire des Sciences de l'Univers-Institut d'écologie et environnement-Centre National de la Recherche Scientifique (CNRS)

Subjects

Paleoceanography, [SDU]Sciences of the Universe [physics], Nd isotopes, North Atlantic Deep Water, Mozambique Channel, Ferromanganese crusts

Abstract

The Mozambique Channel plays a key role in the exchange of water masses between the Indian and Atlantic Oceans, which include the North Atlantic Deep Water (NADW) inflow from the south and the North Indian Deep Water (NIDW), an aged form of the NADW spreading poleward from the northern and equatorial Indian Ocean basin. Several authors assume that the Davie Ridge acts as a topographic barrier to the northward advection of NADW, which would therefore be absent in the Comoros Basin. Other studies suggest that the NADW flows from the south of the Mozambique Channel to the Comoros Basin, indicating that the Davie Ridge may not currently constitute a blocking topographic barrier to deep water mass circulation. To address this question, we studied ferromanganese (Fe, Mn) crusts collected over 2000 km in the Mozambique Channel, from the Agulhas Plateau to the Glorieuses Islands. Neodymium (Nd) isotope compositions (εNd) of surface scrapings range between εNd = −10.1 above the Agulhas Plateau, which might reflect the NADW inflow, and more radiogenic values between εNd = −8.0 and − 8.2 in the Glorieuses area, highlighting the NIDW influence. However, value of εNd = −9.4 measured north of the Davie Ridge cannot be explained by the sole influence of the NIDW and therefore highlights the advection of the NADW northeast of the Comoros Basin. We estimate that the contribution of the NADW through the channel is up to 68% in the Agulhas Plateau and 60% north of the Davie Ridge. These findings are consistent with previous hydrographic studies and suggest that the Davie Ridge does not currently act as topographic barrier to deep currents.

Published

2020

3. A Late Quaternary record of highstand shedding from an isolated carbonate platform (Juan de Nova, southern Indian Ocean).

Author

Counts, John W., Jorry, Stephan J., Vazquez Riveiros, Natalia, Jouet, Gwenael, Giraudeau, Jacques, Cheron, Sandrine, Boissier, Audrey, and Miramontes, Elda

Subjects

CARBONATES, OCEAN, ARAGONITE, OCEAN bottom, AGGRADATION & degradation, TSUNAMI hazard zones, BIOSTRATIGRAPHY

Abstract

A 27 m core collected on the sea floor near Juan de Nova island at 1,909 m depth in the SW Indian Ocean preserves a high‐resolution record of carbonate sediment export to the deep sea over the past 1 Myr. Core chronology was established using calcareous nannofossil biostratigraphy and benthic foraminiferal δ18O. Throughout the core, preserved highstand intervals (MIS 1, 5, 7, 9, 11, 13, 15, 23 and 25) are marked by an increase in the aragonite content within the sediment. Aragonite is likely sourced from the nearby Juan de Nova carbonate platform ca 10 km to the south, and is interpreted as resulting from flooding of the platform top. Platform inundation allows carbonate muds to be winnowed from their original shallow‐water environment of deposition, suspended in the water column, and redeposited onto the proximal slopes and within the basin. Sharp increases in aragonite content at the beginning of each highstand interval can be used to estimate the approximate sea‐level range when platform flooding occurred; results show that the depth of the platform top has likely changed little over the past 1 Myr due to balanced aggradation and subsidence. Previously hypothesized large‐scale aragonite dissolution cycles are evidenced by a disproportionally low aragonite increase during MIS 11. This study provides a new, exceptionally long record of highstand shedding, expanding the known occurrences of the process to the southern Indian Ocean and supporting its importance as a globally significant depositional mechanism that impacts deep‐sea stratigraphic records. [ABSTRACT FROM AUTHOR]

Published

2019

4. Sedimentary evolution and effects of structural controls on the development of the Zambezi mixed turbidite-contourite system (Mozambique Channel, Southwest Indian Ocean) since the Oligocene.

Author

Fierens, Ruth, Droz, Laurence, Jouet, Gwenael, Rabineau, Marina, Raisson, François, Babonneau, Nathalie, Robin, Cécile, and Jorry, Stephan J.

Subjects

*OLIGOCENE Epoch, *TURBIDITES, *LEVEES, *MIOCENE Epoch, *OCEAN

Abstract

High-resolution multichannel seismic reflection data that spans significant parts of the Mozambique margin offshore the Zambezi River permits the study of the Oligocene to present architectural evolution of the Zambezi turbidite system. In this time frame, five major depositional units are recognized that evidence a widespread spatial and temporal occurrence of both turbiditic and contouritic sedimentation. They indicate that the sedimentary regime within the turbidite system changed from dominantly aggradational during the Oligocene to mainly erosional during Miocene to an interplay of erosional and depositional processes during the Plio-Quaternary. Different episodes of incision, linked with the Serpa Pinto, Angoche and Zambezi valleys, are recognized in the upstream portion of the Zambezi Fan and highlight a westward (anticlockwise) shift of feeding axes. The central portion of the Zambezi Valley was affected by a progressive structural doming during the Miocene. The dominance of long-lasting erosional processes generated by the continuous rise of the seabed led to a deep entrenchment of the Zambezi Valley. This tectonically-controlled over-incision is believed to be the cause of the absence of Miocene levees, and has played an important role in the stabilization of the valley at its current position. Finally, our study revealed a quasi-constant development of contourite accumulations since the Late Miocene that occur most often synchronous with turbiditic sedimentation. The present study offers unique insight into the controls and stages of development of one of the largest turbidite systems in the world and demonstrates especially its susceptibility to structural activity. • Multichannel seismic data allows tracking the Oligocene to present architectural evolution of the Zambezi turbidite system. • Five major depositional units demonstrate both turbiditic and contouritic deposits that occur most often synchronously. • Various episodes of incision in the Zambezi Fan evidence multiple shifts of feeding axes since Oligocene. • Progressive structural doming during Late Miocene caused a deep entrenchment of the Zambezi Valley. [ABSTRACT FROM AUTHOR]

Published

2022

5. Quaternary sediment dispersal in the Zambezi turbidite system (SW Indian Ocean).

Author

Fierens, Ruth, Toucanne, Samuel, Droz, Laurence, Jouet, Gwenael, Raisson, François, Jorissen, Elisabeth L., Bayon, Germain, Giraudeau, Jacques, and Jorry, Stephan J.

Subjects

*SETTLING basins, *CONTINENTAL slopes, *TURBIDITY currents, *SEDIMENTS, *COMPOSITION of sediments

Abstract

This study investigates the Late Quaternary sediment distribution of the Zambezi turbidite system (Mozambique Channel, Western Indian Ocean) from a set of piston cores that characterizes the sedimentation in the Intermediate Basin and in the proximal and distal parts of the Zambezi Fan. Sedimentological and geochemical analyses permit to define variations in sediment composition, sediment accumulation rates and timing of turbiditic deposits over the past 720 kyr. Our study reveals low sediment inputs and rare turbiditic deposits in the Zambezi turbidite system, and the deep (>2,500 m) Mozambique Channel in general, over the studied time interval. The reconstruction of the terrigenous flux in the upper part of the system suggests monsoon-related precipitation changes as the main forcing for riverine inputs variability in the Zambezi system. However, the occurrence of turbiditic deposits in the cores suggests that there is no genetic link between their triggering and evolving climate and sea-level conditions, thus emphasizing transformation of failed (slide-generated) sediment from the continental slope as the main initiation process for turbidity currents in the Zambezi system. Finally, our data highlight regional-scale changes in sedimentary facies through time, interpreted as successive 'on-off' switches in the activity of the distal Zambezi Fan, and by extension, regional-scale depocenter shifts. The last one likely occurred at 350 ± 42 kyr, and is concomitant with a significant increase in terrigenous inputs into the proximal Intermediate Basin. It is speculated that this depocenter shift is related to a major southward migration of the Zambezi delta. • Chronostratigraphic record of the Zambezi turbidite system over the last ~700 kyr. • Monsoon-related precipitation drives the riverine inputs in the Zambezi system. • No genetic link between turbidite deposition and climate / sea-level changes in the deep system. • A major distal-to-proximal depocenter shift is recognized at ca. 350 ka. [ABSTRACT FROM AUTHOR]

Published

2020