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Main Authors: Petrovic, Alexander, Lantzsch, Hendrik, Schwenk, Tilmann, Marquardt, J, Titschack, Jürgen, Hanebuth, Till J J
Format: Dataset Open Access
Language:en
Published: PANGAEA 2018
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Online Access:https://doi.org/10.1594/PANGAEA.895801
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author Petrovic, Alexander
Lantzsch, Hendrik
Schwenk, Tilmann
Marquardt, J
Titschack, Jürgen
Hanebuth, Till J J
author_facet Petrovic, Alexander
Lantzsch, Hendrik
Schwenk, Tilmann
Marquardt, J
Titschack, Jürgen
Hanebuth, Till J J
collection Datos científicos de ciencias marinas y ambientales
contents The NW Iberian continental margin is characterised by a complex morphology and by a sedimentary system which was highly dynamic over glacial to interglacial times. The sedimentary history of the continental slope was strongly influenced by the interaction of bottom currents with topographic highs of structural origin leading to the accumulation of several sediment drifts. A combined analysis of gravity cores from different water depth with hydroacoustic data reveals the vertical behaviour of the upper Mediterranean Outflow Water (MOW) core after the Last Glacial Maximum (LGM). A coarser grained interval during Deglacial and early Holocene times (17.2 to 9.9 cal ka BP) points to an increase in bottom current strength. This increase in velocity was probably related to oceanic density fronts, which migrated through the 300 m thick transition zone between the underlying Labrador Sea Water and the overlying MOW. Radiocarbon dates timed the current strengthening to 17.2 cal ka BP, and a following weakening of the bottom current to 13.3 cal ka BP at 1965 m water depth and to 9.9 cal ka BP at 1885 m water depth. The depth-dependent current weakening suggests an upward shifting of the transition zone by 80 m that was related either to an overall shallowing of MOW or a vertical contraction of this water mass. The upward movement happened over a time interval of approximately 3.4 thousand years. In addition sediment core analysis reveals significant lateral heterogeneities within cm to dm thick sediment layers in the contourite drift. These heterogeneities suggest a need of a detailed core coverage across current-influenced deposits for palaeoceanographic studies to minimize misinterpretations.
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_895801
institution PANGAEA
language en
publishDate 2018
publisher PANGAEA
record_format pangaea
spellingShingle Radiocarbon data and element ratio of sediment cores GeoB15628-2 and GeoB15629-2
Petrovic, Alexander
Lantzsch, Hendrik
Schwenk, Tilmann
Marquardt, J
Titschack, Jürgen
Hanebuth, Till J J
Center for Marine Environmental Sciences; MARUM
The NW Iberian continental margin is characterised by a complex morphology and by a sedimentary system which was highly dynamic over glacial to interglacial times. The sedimentary history of the continental slope was strongly influenced by the interaction of bottom currents with topographic highs of structural origin leading to the accumulation of several sediment drifts. A combined analysis of gravity cores from different water depth with hydroacoustic data reveals the vertical behaviour of the upper Mediterranean Outflow Water (MOW) core after the Last Glacial Maximum (LGM). A coarser grained interval during Deglacial and early Holocene times (17.2 to 9.9 cal ka BP) points to an increase in bottom current strength. This increase in velocity was probably related to oceanic density fronts, which migrated through the 300 m thick transition zone between the underlying Labrador Sea Water and the overlying MOW. Radiocarbon dates timed the current strengthening to 17.2 cal ka BP, and a following weakening of the bottom current to 13.3 cal ka BP at 1965 m water depth and to 9.9 cal ka BP at 1885 m water depth. The depth-dependent current weakening suggests an upward shifting of the transition zone by 80 m that was related either to an overall shallowing of MOW or a vertical contraction of this water mass. The upward movement happened over a time interval of approximately 3.4 thousand years. In addition sediment core analysis reveals significant lateral heterogeneities within cm to dm thick sediment layers in the contourite drift. These heterogeneities suggest a need of a detailed core coverage across current-influenced deposits for palaeoceanographic studies to minimize misinterpretations.
title Radiocarbon data and element ratio of sediment cores GeoB15628-2 and GeoB15629-2
topic Center for Marine Environmental Sciences; MARUM
url https://doi.org/10.1594/PANGAEA.895801