PP13B-1419:
Heinrich 0 at the Younger Dryas Termination Offshore Newfoundland
Monday, 15 December 2014
Christof Pearce1,2, John T Andrews3, Anne E Jennings3, Ioanna Bouloubassi4, Marit-Solveig Seidenkrantz2, Antoon Kuijpers5 and Claude Hillaire-Marcel6, (1)Stockholm University, Department of Geological Sciences, Stockholm, Sweden, (2)Aarhus University, Department of Geoscience, Aarhus, Denmark, (3)Institute of Arctic and Alpine Research, Boulder, CO, United States, (4)LOCEAN, University P. M. Curie, Paris, Cedex 05, France, (5)Geological Survey of Denmark and Greenland, Copenhagen, Denmark, (6)University of Quebec at Montreal UQAM, Montreal, QC, Canada
Abstract:
The last deglaciation was marked by intervals of rapid climatic fluctuations accompanied by glacial advances and retreats along the eastern edge of the Laurentide ice sheet. The most severe of these events, the Younger Dryas cold reversal, was accompanied by the major detrital carbonate (DC) event generally referred to as “Heinrich event 0” (H0) in the westernmost and southern Labrador Sea. A detrital carbonate layer was observed in a high resolution marine sediment record from southern Newfoundland and the onset of the event was dated to 11,600 ± 70 cal. yrs. BP (local ΔR = 140 yrs.). A variety of different proxies was applied to investigate the transport mechanisms for deposition of the layer and provenance of the carbonates. Elevated concentrations of dolomite and calcite based on quantitative X-ray diffraction measurements, combined with the presence of several mature petrogenic biomarkers limit the source of the H0 detrital input to Palaeozoic carbonate outcrops in north-eastern Canada. The event is attributed to the rapid ice retreat from the Hudson Strait directly following the warming at the onset of the Holocene. Based on additional proxy data published earlier from the same record, the event succeeded the early Holocene resumption of the Atlantic Meridional Overturning Circulation (AMOC), indicating that the Hudson Strait meltwater event had probably no significant impact on the AMOC. The detrital carbonate layer can be found in other marine sediment records along the Labrador Current pathway, from Hudson Strait to the Grand Banks and the southern Newfoundland slope. By using the onset of deposition of the carbonates as a time-synchronous marker, the DC layer has great potential for improving marine chronologies of late glacial age in the region and evaluating spatial variations in ΔR values.