Marcel.li Farran

Seafloor evidence of a subglacial sedimentary system off the northern Antarctic Peninsula

Swath-bathymetry data and high-resolution seismic reflection profiles allow us to portray a subglacial sedimentary system off the northern tip of the Antarctic Peninsula, in the Central Bransfield Basin, during the Last Glacial Maximum with unprecedented detail. Postglacial reworking and sedimentation are weak enough for the subglacial morphology of the Last Glacial Maximum to be preserved on the present seafloor. The studied sedimentary system extends 250 km, from ∼1000 m above sea level to ∼2000 m water depth. The data set supports a model for subglacial sedimentary systems that consists of: (1) an upper ice catchment or erosional zone on the innermost continental shelf, extending onshore; (2) a transitional erosional-depositional zone on the inner shelf with drumlinized seafloor; (3) a depositional outer shelf zone with mega-scale bundle glacial lineations; and (4) a debris apron on the continental slope and base of slope formed under floating ice shelves with debris delivery linked to grounding lines along the shelf break.

The Magdalena Turbidite System (Caribbean Sea): present-day morphology and architecture model

Abstract A detailed analysis of the modern morphology, acoustic facies and architecture of the eastern Magdalena Turbidite System has been based on multibeam bathymetry and backscatter data. In spite of the fact that the Magdalena Turbidite System developed in a tectonically active setting, its present architecture model is comprised of two tecto-sedimentary provinces: deformed-constructional and undeformed-erosive. The deformed province occurs where the deformed prism developed. This prism is characterised by structural highs and associated small-scale ridges and scarps. In this province, the Magdalena Turbidite System is constructional because sediment coming from the Colombian hinterland (via the Magdalena River and from coastal erosion) and sediment remobilised from the walls of the structural highs are transported trough canyons and gullies, and emplaced as gravity deposits into the deformed prism. In the undeformed province, by contrast, the Magdalena Turbidite System displays an architecture model similar to a passive continental margin, and is characterised by large-scale mass-flow deposits, leveed channel complexes, scars of slumps, and sediment waves. This province is presently erosive because the existing leveed channels are partially or totally destroyed and cannibalised by mass-flow deposits, cut by small-scale scars of slumps, and their morphology is subdued or modified by the formation of a sediment wave field.

Progradation and retreat of the Valencia fanlobes controlled by sea-level changes during the Plio-Pleistocene (northwestern Mediterranean)

Abstract The Valencia Fan developed in the Valencia Trough at the lower end of the Valencia Valley and the Blanes Canyon. The morpho-sedimentary features of the upper, middle and lower fan, studied from high-resolution sparker reflection profiles, indicate cyclic updip-downdip migrations of fan depocenters during the Plio-Pleistocene. These migrations were caused by changes of sediment input related to the Plio-Pleistocene climatic-eustatic sea-level variations. During periods of sea-level lowering, the system migrated downbasin and developed extensively on the deeper sectors of the Valencia Trough. During periods of sea-level rise, the fan sedimentation migrated updip, abandoning the deeper areas of the basin. The Valencia Fan is not affected by significant lateral migration because it developed in a basin constricted between two land masses. As a consequence, longitudinal progradation and retreat of fan deposition produced a vertical stacking of fanlobes displaced alternatively updip and downdip. These growth patterns reveal some differences with respect to classical deep-sea fans.

The Equatorial Atlantic Mid-Ocean Channel: An Ultra High-Resolution Image of Its Burial History Based on TOPAS Profiles

Multibeam bathymetric and ultra high-resolution seismic data reveal that the distal course of the Equatorial Atlantic Mid-Ocean Channel (EAMOC) extends further east and south than was previously known, and is controlled by the presence of morphologic highs related to the Fernando de Noronha Fracture Zone. Distal course of the EAMOC is buried by sediments, and does not have bathymetric expression on the seafloor. The channel fill consists of three seismic sequences, suggesting that the recent geological evolution of the channel is composed of successive phases of decreasing sedimentary activity that finally resulted in its complete burial. Tectonic and volcanic activity related to the Fernando de Noronha Fracture Zone and Ridge, together with the effect of strong pulses of the Antarctic bottom water current during the upper Pliocene are suggested to have contributed to the progressive burial and the final abandonment of the EAMOC.