Nd and Pb isotope signatures of the clay-size fraction of Labrador Sea sediments during the Holocene: Implications for the inception of the modern deep circulation pattern
clay mineral; sedimentary mixings; deep circulation; Nd and Pb isotopes; North Atlantic Ocean; Labrador Sea
Abstract :
[en] Nd and Pb isotopes were measured on the fine fraction of one sediment core drilled off southern Greenland. This work aims to reconstruct the evolution of deep circulation patterns in the North Atlantic during the Holocene on the basis of sediment supply variations. For the last 12 kyr, three sources have contributed to the sediment mixture: the North American Shield, the Pan-African and Variscan crusts, and the Mid-Atlantic Ridge. Clay isotope signatures indicate two mixtures of sediment sources. The first mixture (12.2-6.5 ka) is composed of material derived from the North American shield and from a "young'' crustal source. From 6.5 ka onward the mixture is characterized by a young crustal component and by a volcanic component characteristic of the Mid-Atlantic Ridge. Since the significant decrease in proximal deglacial supplies, the evolution of the relative contributions of the sediment sources suggests major changes in the relative contributions of the deep water masses carried by the Western Boundary Undercurrent over the past 8.4 kyr. The progressive intensification of the Western Boundary Undercurrent was initially associated mainly with the transport of the Northeast Atlantic Deep Water mass until 6.5 ka and with the Denmark Strait Overflow Water thereafter. The establishment of the modern circulation at 3 ka suggests a reduced influence of the Denmark Strait Overflow Water, synchronous with the full appearance of the Labrador Seawater mass. Our isotopic data set emphasizes several changes in the relative contribution of the two major components of North Atlantic Deep Water throughout the Holocene.
Fagel, Nathalie ; Université de Liège - ULiège > Département de géologie > Géochim. sédiment. - Sédiment. mar. & continent. du quatern.
Hillaire-Marcel, Claude ; Université de Liège - ULiège > Géochim. sédiment. - Sédiment. mar. & continent. du quatern.
Humblet, Marc
Brasseur, Robert ; Université de Liège - ULiège > Département de géologie
Weis, D.; University of British Columbia - UBC > Pacific Center for Isotopic and Geochemical Research
Stevenson, Ross; Université du Québec à Montréal > Centre de Recherches en Géochimie et Géodynamique (GEOTOP)
Language :
English
Title :
Nd and Pb isotope signatures of the clay-size fraction of Labrador Sea sediments during the Holocene: Implications for the inception of the modern deep circulation pattern
Publication date :
07 July 2004
Journal title :
Paleoceanography
ISSN :
0883-8305
eISSN :
1944-9186
Publisher :
Amer Geophysical Union, Washington, United States - Washington
Volume :
19
Issue :
3
Peer reviewed :
Peer Reviewed verified by ORBi
Funders :
CRSNG - Conseil de Recherches en Sciences naturelles et en Génie F.R.S.-FNRS - Fonds de la Recherche Scientifique
Commentary :
An edited version of this paper was published by AGU. Copyright (2004) American Geophysical Union.
Andrews, J. T., J. Hardadottir, J. S. Stoner, M. E. Mann, G. B. Kristjansdottir, and N. Koc (2003), Decadal- to millennial-scale periodicities in north Iceland shelf sediments over the last 12,000 cal yr: Long-term North Atlantic oceanographic variability and solar forcing, Earth Planet. Sci. Lett., 210, 453-465.
Barber, D. C., et al. (1999), Forcing the cold event of 8200 years ago by catastrophic drainage of Laurentide lakes, Nature, 400, 344-348.
Bilodeau, G., A. de Vernal, and C. Hillaire-Marcel (1994), Benthic foraminiferal assemblages in Labrador Sea sediments: Relations with deep-water mass changes since the deglaciation, Can. J. Earth Sci., 31, 128-138.
Biscaye, P. E. (1965), Mineralogy and sedimentation of recent deep-sea clay in the Atlantic and adjacent seas and oceans, Geol. Soc. Am. Bull., 76, 803-832.
Boski, T., J. Pessoa, P. Pedro, J. Thorez, J. M. A. Dias, and I. R. Hall (1998), Factors governing abundance of hydrolysable amino acids in the sediments from the NW European continental margin (47-50°N), Prog. Oceanogr., 42, 145-164.
Boyle, E. A. (1995), Last Glacial Maximum North Atlantic Deep Water: On, off or somewhere in between? Philos, Trans. R. Soc. London Ser. A, 348, 243-253.
Brasseur, R. (2002), Evolution de la signature isotopique en Pb des sédiments de la Mer du labrador au cours de l'Holocène: Implications sur la circulation océanique profonde en Atlantique Nord, Mem. DEA, Oceanogr., 66 pp., Univ. of Liège, Liège.
Bridgewater, D., M. Marker, and F. Mengel (1991), The eastern extension of the early Proterozoic orogenic zone across the Atlantic, Rep. ECSOOT Transect Meet., 34, 100-107.
Broecker, W. S., and G. H. Denton (1989), The role of ocean-atmosphere reorganisation in glacial cycle, Geochim. Cosmochim. Acta, 53, 63-89.
Campbell, L. M., D. Bridgewater, and G. L. Farmer (1996), A comparison of Proterozoic crustal formation along the Torngat-Nagssugqtoqidian-Lapland collision belts: Preliminary constraints from Nd and Pb isotopic studies in northern Labrador, Rep. ECSOOT Transect Meet., 45, 22 36.
Clarke, G., D. Leverington, J. Teller, and A. Dyke (2003), Enhanced: Superlakes, megafloods and abrupt climate change, Science, 301, 922-923.
de Vernal, A., C. Hillaire-Marcel, J. L. Thuron, and J. Matthiessen (2000), Reconstruction of sea surface temperature, salinity, and sea ice cover in the northern North Atlantic during the Last Glacial Maximum based on dinocyst assemblages, Can. J. Earth Sci., 37, 725-750.
Dia, A., B. Dupré, and C. J. Allègre (1992), Nd isotopes in Indian Ocean used as a tracer of supply to the ocean and circulation paths, Mar. Geol., 103, 349-359.
Dickson, R. R., and J. Brown (1994), The production of North Atlantic Deep Water: Sources, rates, and pathways, J. Geophys. Res., 99, 12,319-12,341.
Duplessy, J.-C., E. Ivanova, I. Murdmaa, M. Paterne, and L. Labeyrie (2001), Holocene paleoceanography of the northern Barents Sea and variations in the northward heat transport of the Atlantic Ocean, Boreas, 30, 2-16.
Fagel, N., C. Hillaire-Marcel, and C. Robert (1997), Changes in the Western Boundary Undercurrent outflow since the Last Glacial Maximum, from smectite/illite ratios in deep Labrador Sea sediments, Paleoceanography, 12, 79-96.
Fagel, N., C. Innocent, R. K. Stevenson, and C. Hillaire-Marcel (1999), Deep circulation changes in the Labrador Sea since the Last Glacial Maximum: New constraints from Sm-Nd data on sediments, Paleoceanography, 14, 777-788.
Fagel, N., C. Innocent, C. Gariépy, and C. Hillaire-Marcel (2002), Sources of Labrador Sea sediments since the Last Glacial Maximum inferred from Nd-Pb isotopes, Geochim. Cosmochim. Acta, 66, 2569-2581.
Fagel, N., T. Boski, L. Likhoshway, and H. Oberhaensli (2003), Late Quaternary clay mineral record in Central Lake Baikal (Acdemician Ridge Siberia), Palaeogeogr. Palaeoecol. Palaeoecol.,193,159-179.
Faure, G. (1986), Principles of Isotope Geology, 589 pp., John Wiley, Hoboken, N. J.
Folk, R. L., and W. C. Ward (1957), Brazos River bar: A study in the significance of grain-size parameters, J. Sediment. PetroL, 27, 3-26.
Frank, M. (2002), Radiogenic isotopes: Tracers of past ocean circulation and erosional input, Rev. Geophys., 40(1), 1001, doi: 10.1029/2000RG000094.
Funder, S. (1989), Quaternary geology of the ice-free areas and adjacent shelves of Greenland, in Quaternary Geology of Canada and Greenland, Geology of Canada, edited by R. J. Fulton, pp. 743-792, Geol. Surv. of Can., Ottawa, Ont.
Galer, S. J. G. (1999), Optimal double and triple spiking for high precision lead isotopic measurement, Chem. Geol., 154, 255-274.
Hansen, B., and S. Osterhus (2000), North Atlantic-Nordic Seas exchanges, Prog. Oceanogr., 45, 109-208.
Hillaire-Marcel, C., A. De Vernal, G. Bilodeau, and G. Wu (1994), Isotope stratigraphy, sedimentation rates, deep circulation and carbonate events in the Labrador Sea during the last ∼200 ka, Can. J. Earth Sci., 31, 63-89.
Hillaire-Marcel, C., A. de Vernal, G. Bilodeau, and A. J. Weaver (2001a), Absence of deep water formation in the Labrador Sea during the last interglacial period, Nature, 410, 1073-1077.
Hillaire-Marcel, C., A. de Vernal, G. Bilodeau, and J. Stoner (2001b), Changes of potential density gradients in the northwestern North Atlantic during the last climatic cycle, based on a multi-proxy approach, in The Oceans and Rapid Climate Change: Past, Present, and Future, Geophys. Monogr. Ser., vol. 126, edited by D. Seidov et al., pp. 83-100, AGU, Washington, D. C.
Hillaire-Marcel, C., A. de Vernal, L. Polyak, and D. Darby (2004), Size dependent isotopic compositions of planktic foraminifers from the Chukchi Sea vs. NW Atlantic sediments - Implications for the Holocene paleoceanography of the western Arctic, Quat. Sci. Rev., 23, 245-260.
Humblet, M. (2002), Evolution de la signature isotopique en Nd et Sm des sédiments de la Mer du Labrador au cours de l'Holocène: Implications sur la circulation océanique profonde en Atlantique Nord, Mem. DEA, Oceanogr., 76 pp., Univ. of Liège, Liège.
Innocent, C., N. Fagel, R. K. Stevenson, and C. Hillaire-Marcel (1997), Sm-Nd signature of modern and late Quaternary sediments from the northwest North Atlantic: Implications for deep current changes since the Last Glacial Maximum, Earth Planet. Sci. Lett., 146, 607-625.
Jansson, K. N. (2003), Early Holocene glacial lakes and ice marginal retreat pattern in Labrador/Ungava, Canada, Palaeogeogr. Palaeoclimatol. Palaeoecol., 193, 473-501.
Kalsbeek, F., H. Austrheim, D. Bridgewater, B. T. Hansen, S. Pedersen, and P. N. Taylor (1993), Geochronology of Archaean and Proterozoic events in the Ammassalik area, southeast Greenland, and comparisons with the Lewisian of Scotland and the Nagssugtoqidian of west Greenland, Precambrian Res., 62, 239-270.
Kuijpers, A., S. R. Troestra, M. A. Prins, K. Linthout, A. Akhmetzhanov, S. Bouryak, M. F. Bachmann, S. Lassen, S. Rasmussen, and J. B. Jensen (2003), Late Quaternary sedimentary processes and ocean circulation changes at the southeast Greenland margin, Mar. Geol., 195, 109-129.
Lacan, F., and C. Jeandel (2004), Denmark Strait Water circulation traced by heterogeneity in neodymium isotopic compositions, Deep Sea Res., 51, 71-82.
Ledbetter, M. T., and W. M. Balsam (1985), Paleoceanography of the deep western boundary undercurrrent on the North American continental margin for the past 25,000 yr, Geology, 13, 181-184.
Licciardi, J. M., J. T. Teller, and P. U. Clark (1999), Freshwater routing by the Laurentide ice sheet during the last deglaciation, in Mechanisms of Global Climate Change at Millennial Time Scales, Geophys. Monogr. Ser., vol. 112, edited by P. U. Clark, R. S. Webb, and L.D. Keigwin,pp. 177 201,AGU, Washington, D.C.
Lucotte, M., and C. Hillaire-Marcel (1994), Identification des masses d'eau dans les mers du Labrador et d'Irminger, Can. J. Earth Sci., 31 5-13.
Manhès, G., J. F. Minster, and C. J. Allègre (1978), Comparative uranium-thorium-lead and rubidium-strontium study of the Saint-Séverin amphoterite: Consequences for early solar system chronology, Earth Planet. Sci. Lett., 39, 14-24.
McCartney, M. S. (1992), Recirculating components to the deep boundary current of the northern North Atlantic, Prog. Oceanogr., 29, 283-383.
McCave, I. N., B. Manighetti, and N. A. S. Beveridge (1995), Circulation in the glacial North Atlantic inferred from grain-size measurements, Nature, 374, 149-151.
Moore, D. M., and R. C. Reynolds (1989),X-Ray Diffraction and the Identification and Analysis of Clay Minerals, 332 pp., Oxford Univ. Press, New York.
Rasmussen, T. L., D. Bâckstrôm, J. Heinemeier, D. Klitgaard-Kristensen, P. C. Knutz, A. Kuijpers, S. Lassen, E. Thomsen, S. R. Troelstra, and T. C. E. van Weering (2002), The Faroe-Shetland gateway: Late Quaternary water mass exchange between the Nordic seas and the northeastern Atlantic, Mar. Geol., 188, 165-192.
Revell, M., M. Cremer, F. E. Grousset, and L. Labeyrie (1996), Grain-size and Sr-Nd isotopes as tracer of paleo-bottom current strength, northeast Atlantic Ocean, Mar. Geol., 131, 233-249.
Rosman, K. J. R., and P. D. P. Taylor (1998), Isotopic compositions of the elements 1997, Pure Appl. Chem., 70, 217-236.
Sarnthein, M., K. Winn, S. Jung, J. Duplessy, L. Labeyrie, H. Erlenkeuser, and G. Ganssen (1994), Changes in east Atlantic deepwater circulation over the last 30,000 years: Eight time slice reconstructions, Paleoceanography, 9(2), 209-268.
Schmitz, W. J., and M. S. McCartney (1993), On the North Atlantic circulation, Rev. Geophys., 31, 29-49.
Solignac, S., A. de Vernal, and C. Hillaire-Marcel (2004), Holocene sea-surface conditions in the North Atlantic - Contrasted trends and regimes between the eastern and western sectors (Labrador Sea vs. Iceland Basin), Quat. Sci. Rev., 23, 319-334.
St-Onge, G., J. S. Stoner, and C. Hillaire-Marcel (2003), Holocene paleomagnetic records from the St. Lawrence Estuary, eastern Canada: Centennial- to millennial-scale geomagnetic modulation of cosmogenic isotopes, Earth Planet. Sci. Lett., 209, 113-130.
Stuiver, M., and P. J. Reimer (1993), Extended 14C data base and revised CALIB3.0 14C age calibration program, Radiocarbon, 35, 215-230.
Turon, J. L., et al. (1999), Images V, à bord du "Marion Dufresne", 2e Leg du 30 juin au 24 juillet 1999, Rapp. Mission 99-X, Inst. Fr. de Rech. en Terres Polaires, Brest.
Veiga-Pires, C. C., and C. Hillaire-Marcel (1998), U and Th isotope constraints on the duration of Heinrich events H0 - H4 in the southern Labrador Sea, Paleoceanography, 14, 187-199.
von Blanckenburg, F., and T. F. Nägler (2001), Weathering versus circulation-controlled changes in radiogenic isotope tracer composition of the Labrador Sea and North Atlantic Deep Water, Paleoceanography, 16, 424-434.
Wasserburg, G. J., S. B. Jacobsen, D. J. De Paolo, M. T. McCulloch, and T. Wen (1981), Precise determination of Sm/Nd ratios, Sm and Nd isotopic abundances in standard solutions, Geochim. Cosmochim. Acta, 45, 2311-2323.
White, W. M., F. Albarède, and P. Télouk (2000), High-precision analysis of Pb isotopic ratios using multi-collector ICP-MS, Chem. Geol., 167, 257-270.
