Réponse de la productivité diatomique aux changements climatiques et océanographiques au niveau du système turbiditique du Congo au cours du dernier million d'années / Diatom response to oceanographic and climatic changes in the Congo deep sea fan area during the last million years

Hatin, Tristan

22 September 2016

Pour préciser l’architecture du système turbiditique du Congo (marge Ouest-Africaine, Atlantique Sud-Est), et les variations climatiques et paléocéanographiques de la zone au cours du dernier million d’années, on a étudié les variations de la productivité des diatomées sur deux carottes de référence, KZAI-02 et RZCS-26, prélevées respectivement à 248 et 800 Kms de l’embouchure du fleuve. Cette étude est intégrée au projet REPREZAÏ, REtrogradation/PRogradation dans l’Eventail du ZAÏre, Les périodes de forte productivité diatomique sont observées vers le milieu du stade MIS6, le MIS 5d, et durant le MIS 3, liées à l’apport de nutriments, notamment la silice dissoute, par le fleuve. Les faibles taux d’accumulation en diatomées sont enregistrés au début et à la fin du MIS 6, le MIS 5e, le début du MIS 4 et l’Holocène, quand la charge terrigène dans les eaux de surface empêche la mise en place d’une forte productivité. Au large il faut un apport conséquent de silice dissoute via les décharges du fleuve, et une faible consommation de ce nutriment en amont, pour avoir une forte productivité. L’intensification des conditions d’upwelling océanique favorise la productivité diatomique. L’abondance des diatomées d’estuaires saumâtres coïncide avec l’augmentation de l’influence des décharges fluviatiles vers ~230 ka BP, période de mise en place de l’édifice axial du système turbiditique du Congo. Deux études exploratoires ont été menées en complément: L’étude de la variabilité morphométrique de l’espèce Fragilariopsis doliolus qui montre une variation importante de la surface valvaire au cours du Quaternaire ; l’étude des isotopes de la silice qui s’est avérée complexe, à cause du mélange important de silice biogénique et lithogénique dans nos échantillons. / To precise the evolution of the Congo deep sea fan (western African margin, eastern tropical South Atlantic), and the paleoclimatic and paleoceanographic conditions of the zone during the last million years, variations of diatom productivity have been studied on two reference cores, KZAI-02 and RZCS-26, located respectively at 240 and 800 Kms of the Congo river mouth. This study is part of the REPREZAI project, REtrogradation/PRogradation in the ZAÏre deep-sea fan. High diatom accumulation rates were registered during the mid-part of MIS 6, the cold substage MIS 5d and the MIS 3-2, sustained essentially via nutrients, including dissolved silica, injected by the Congo River into the ocean. Low diatom accumulation rates were recorded during the early and late MIS 6, the MIS 5e, the early MIS 4 and the Holocene, when the terrigenous load in surface waters prevent a strong productivity. Further offshore, a substantial dissolved silica input by the discharges of the Congo river, but also a low consumption of this nutrient upstream, are required to have a strong productivity. The intensification of oceanic upwelling conditions also favors the siliceous productivity. The increasing influence of fluvial discharges, marked by a greater abundance of brackish diatoms off the mouth, corresponds fairly well to the establishment of the axial edifice of the Congo deep sea fan around ~ 230 ka BP. Two exploratory studies were conducted in complement: The study of morphometric variability of the diatom species Fragilariopsis doliolus, that highlighted important variation of the valvar surface during the Quaternary; the study of the silica isotopes that proved to be complex, because of important mix of biogenic and lithogenic silica in the samples.

Diatomées

Productivité

Quaternaire

Système turbiditique du Congo

Silice

Diatoms

Productivity

Late Quaternary

Congo fan area

Silica

579.85

The biogeochemical source and role of soluble organic-Fe(III) complexes in continental margin sediments

Beckler, Jordon Scott

12 January 2015

In the past couple of decades, the discovery that iron is a limiting nutrient in large regions of the ocean has spurred much research into characterizing the biogeochemical controls on iron cycling. While Fe(II) is soluble at circumneutral pH, it readily oxidizes to Fe(III) in the presence of oxygen. Fe(III) is highly insoluble at circumneutral pH, presenting organisms with a bioavailability paradox stemming from the physiological challenge of using a solid phase mineral for assimilatory or dissimilatory purposes. Interestingly, dissolved organic-Fe(III) complexes can be stable in seawater in the presence of oxygen, and an active flux of these complexes has recently been measured in estuarine sediments. Their sources and biogeochemical role, however, remain poorly understood. In this work, a suite of field and laboratory techniques were developed to quantify diagenetic processes involved in the remineralization of carbon in marine sediments in situ, investigate the role of these organic-Fe(III) complexes in sediment biogeochemistry, and characterize the composition of the ligands possibly involved in the solubilization of Fe(III) in marine sediments. The first-of-its-kind in situ electrochemical analyzer and HPLC was used to better constrain diagenetic processes that may lead to the formation of dissolved organic-Fe(III) complexes in the Altamaha estuary and Carolina slope. An intensive study of the Satilla River estuary reveals that dissimilatory iron-reduction contributes to the formation of sedimentary organic-Fe(III) complexes, which are demonstrated to serve as an electron acceptor in subsequent incubations with a model iron-reducing microorganism. Similar observations in deep-sea slope and abyssal plain sediments fed by the Mississippi and Congo Rivers suggest that dissimilatory iron reduction may represent an important component of carbon remineralization in river-dominated ocean margin sediments that may be currently underestimated globally. To confirm that these organic-Fe(III) complexes are produced during microbial iron reduction, novel separation schemes were developed to extract and identify Fe(III)-binding ligands from sediment pore waters. Preliminary results reveal the presence of a few select low-molecular weight compounds in all pore waters extracted, suggesting they might be endogenous ligands secreted by iron-reducing bacteria to non-reductively dissolve Fe(III) minerals prior to reduction.

Iron

Ocean

Marine

Organic ligands

HPLC

In-situ measurements

Congo fan

Louisiana slope

Hatteras slope

Satilla River

IMAC

HP-SEC

LC/ESI-MS

Anions

Shewanella

Deep-sea sediment