Saved in:
Bibliographic Details
Main Authors: Beaudouin, Célia, Dennielou, Bernard, Melki, Tarek, Guichard, Francois, Kallel, Nejib, Berné, Serge, Huchon, Agnes
Format: Dataset Open Access
Language:en
Published: PANGAEA 2004
Subjects:
Online Access:https://doi.org/10.1594/PANGAEA.740914
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1867167663631892480
author Beaudouin, Célia
Dennielou, Bernard
Melki, Tarek
Guichard, Francois
Kallel, Nejib
Berné, Serge
Huchon, Agnes
author_facet Beaudouin, Célia
Dennielou, Bernard
Melki, Tarek
Guichard, Francois
Kallel, Nejib
Berné, Serge
Huchon, Agnes
collection Datos científicos de ciencias marinas y ambientales
contents Siliciclastic turbidites represent huge volumes of sediments, which are of particular significance for (1) petroleum researchers, interested in their potential as oil reservoirs and (2) sedimentologists, who aim at understanding sediment transport processes from continent to deep-basins. An important challenge when studying marine turbidites has been to establish a reliable chronology for the deposits. Indeed, conventional marine proxies applied to hemipelagic sediments are often unreliable in detrital clays. In siliciclastic turbidites, those proxies can be used only in hemipelagic intervals, providing a poor constraint on their chronology. In this study, we have used sediments from the Rhône Neofan (NW Mediterranean Sea) to demonstrate that pollen grains can provide a high-resolution chronostratigraphical framework for detrital clays in turbidites. Vegetation changes occurring from the end of Marine Isotopic Stage 3 to the end of Marine Isotopic Stage 2 (from ~30 to ~18 ka cal. BP) are clearly recorded where other proxies have failed previously, mainly because the scarcity of foraminifers in these sediments prevented any continuous Sea Surface Temperature (SST) record and radiocarbon dating to be obtained. We show also that the use of palynology in turbidite deposits is able to contribute to oceanographical and sedimentological purposes: (1) Pinus pollen grains can document the timing of sea-level rise, (2) the ratio between pollen grains transported from the continent via rivers and dinoflagellate cysts (elutriating) allows us to distinguish clearly detrital sediments from pelagic clays. Finally, taken together, all these tools show evidence that the Rhône River disconnected from the canyon during the sea-level rise and thus evidence the subsequent rapid starvation of the neofan at 18.5 ka cal. BP. Younger sediments are hemipelagic: the frequency of foraminifers allowed to date sediments with radiocarbon. First results of Sea Surface Temperature obtained on foraminifers are in good agreement with the dinoflagellate cysts climatic signal. Both provide information on the end of the deglaciation and the Holocene.
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_740914
institution PANGAEA
language en
publishDate 2004
publisher PANGAEA
record_format pangaea
spellingShingle Age determination of sediment cores of the Golf of Lions
Beaudouin, Célia
Dennielou, Bernard
Melki, Tarek
Guichard, Francois
Kallel, Nejib
Berné, Serge
Huchon, Agnes
93C12; 99; CALYPSO; Calypso Corer; Gulf of Lions; IMAGES V; KULC; KULLENBERG corer; Marion Dufresne (1995); MD114; MD99-2344; Neofan; Pnoc; Profiles across Mediterranean Sedimentary Systems; PROMESS
Siliciclastic turbidites represent huge volumes of sediments, which are of particular significance for (1) petroleum researchers, interested in their potential as oil reservoirs and (2) sedimentologists, who aim at understanding sediment transport processes from continent to deep-basins. An important challenge when studying marine turbidites has been to establish a reliable chronology for the deposits. Indeed, conventional marine proxies applied to hemipelagic sediments are often unreliable in detrital clays. In siliciclastic turbidites, those proxies can be used only in hemipelagic intervals, providing a poor constraint on their chronology. In this study, we have used sediments from the Rhône Neofan (NW Mediterranean Sea) to demonstrate that pollen grains can provide a high-resolution chronostratigraphical framework for detrital clays in turbidites. Vegetation changes occurring from the end of Marine Isotopic Stage 3 to the end of Marine Isotopic Stage 2 (from ~30 to ~18 ka cal. BP) are clearly recorded where other proxies have failed previously, mainly because the scarcity of foraminifers in these sediments prevented any continuous Sea Surface Temperature (SST) record and radiocarbon dating to be obtained. We show also that the use of palynology in turbidite deposits is able to contribute to oceanographical and sedimentological purposes: (1) Pinus pollen grains can document the timing of sea-level rise, (2) the ratio between pollen grains transported from the continent via rivers and dinoflagellate cysts (elutriating) allows us to distinguish clearly detrital sediments from pelagic clays. Finally, taken together, all these tools show evidence that the Rhône River disconnected from the canyon during the sea-level rise and thus evidence the subsequent rapid starvation of the neofan at 18.5 ka cal. BP. Younger sediments are hemipelagic: the frequency of foraminifers allowed to date sediments with radiocarbon. First results of Sea Surface Temperature obtained on foraminifers are in good agreement with the dinoflagellate cysts climatic signal. Both provide information on the end of the deglaciation and the Holocene.
title Age determination of sediment cores of the Golf of Lions
topic 93C12; 99; CALYPSO; Calypso Corer; Gulf of Lions; IMAGES V; KULC; KULLENBERG corer; Marion Dufresne (1995); MD114; MD99-2344; Neofan; Pnoc; Profiles across Mediterranean Sedimentary Systems; PROMESS
url https://doi.org/10.1594/PANGAEA.740914