24 research outputs found
Multi-proxy speleothem-based reconstruction of mid-MIS 3 climate in South Africa
The southern coast of South Africa displays a highly dynamical climate as it is at the convergence of both the Atlantic and Indian Ocean, and it is located near the subtropical/temperate zone boundary with seasonal influence of easterlies/westerlies. The region hosts some key archeological sites with records of significant cognitive, technological and social developments. Reconstructions of the state and variability of past climate and environmental conditions around sites of archeological significance can provide crucial context for understanding the evolution of early humans. Here we present a short but high-resolution record of hydroclimate and temperature in South Africa. Our reconstructions are based on trace elements, calcite and fluid inclusion stable isotopes, and fluid inclusion microthermometry from a speleothem collected in Bloukrantz Cave, in the De Hoop Nature Reserve in the Western Cape region of South Africa. Our record covers the time period from 48.3 to 45.2 ka during Marine Isotope Stage 3. Both 18Oc and 13Cc show strong variability and covary with Sr/Ca. This correlation suggests that the control on these proxies originates from internal cave processes such as Prior Calcite Precipitation, which we infer to be related to precipitation amount. The hydroclimate indicators furthermore suggest a shift towards overall drier conditions after 46 ka, coincident with a cooling in Antarctica and drier conditions in the eastern part of South Africa corresponding to the Summer Rainfall Zone. Fluid inclusion-based temperature reconstructions show good agreement between the oxygen isotope and microthermometry methods, and results from the latter display little variation throughout the record, with reconstructed temperatures close to the present-day cave temperature of 17.5 °C. Overall, the BL3 record thus suggests stable temperature from 48.3 to 45.2 ka whereas precipitation was variable with marked drier episodes on sub-millennial timescales.</p
Geochimical and isotopic properties of Fram strait sediments , Artic Ocean. A paleoceanographic and paleoclimatic approach
Les flux d'eau douce, glace de mer et courants océaniques, de l'Océan Arctique vers les mers nordiques jouent un rôle critique sur l'Atlantic Meridional Overturning Circulation et donc sur le système climatique. Les facteurs contrôlant ces flux sont encore partiellement méconnus. Un moyen indirect de retracer l'intensité et les schémas de circulation de la glace de mer est de retracer l'origine des sédiments qu'elle transporte, et qui sédimentent le long des grands courants de glace et d'eau douce vers l'Atlantique Nord. Il s'agit donc de tracer un flux particulaire direct, lié à la matrice des particules détritiques. Un second flux, indirect, provient des éléments dissous dans les masses d'eau, marqués par les processus d'adsorption/désorption le long des marges où les flux particulaires terrigènes sont les plus importants. L'extraction de la phase authigène d'un signal dissous par lessivage spécifique, a permis de documenter l'évolution des masses d'eau transitant par le détroit de Fram. Les données isotopiques de Pb, Nd et Sr nous ont permis d'identifier deux sources principales de sédiments depuis le dernier maximum glaciaire jusqu'au Dryas Récent : les marges canadiennes et russes alors recouvertes par des calottes de glace. Après le Dryas Récent, les sources sédimentaires sont plus diverses avec notamment une contribution des marges groenlandaises et des mers de Chukchi et Est Sibérienne. La fraction authigène montre un changement entre ~ 19.8 et 16.4 ka probablement liée à la déglaciation de la calotte Eurasienne. Plus récemment, les valeurs [Epsilon]Nd suggèrent une influence accrue des eaux Pacifiques sur les masses d'eaux sortantes par le détroit de FramFreshwater exports (sea-ice and oceanic currents) from the Arctic Ocean to the nordic seas is a critical component of the Atlantic Meridional Overturning Circulation and hence of the climatic system. Factors controling those exports are still partially unknown. An indirect way of tracing the intensity and patterns of sea-ice circulation is to trace the origin of the sediments it carries and that settle along the main drift routes towards the North Atlantic. We hence document a direct sedimentary flux that is linked to the detrital particle matrices. Another flux, this one being indirect, comes from the dissolved elements that adsorb onto particles along continental margins where sedimentary fluxes are the highest. We have extracted the authigenic (dissolved) phase from the sediment in order document the evolution of water-masses in Fram Strait since the last glacial maximum. Pb, Nd and Sr isotopic data allowed us to identify two sedimentary sources from the late glacial to the onset of the younger Dryas : canadian and western russian margins, then covered by large ice sheets. After the Younger Dryas however, sedimentary supplies originate from several sources including Greeland, Chukchi Sea and East Siberian Sea margins. The authigenic phase displays a change from 19.8 to 16.4 ka likely linked to the early deglaciation of the Eurasian ice sheet. More recently, [Epsilon]Nd values reflect a more important contribution from the Pacific on water masses exiting through Fram Strai
Propriétés géochimiques et isotopiqes des sédiments du détroit de Fram, Océan Arctique. Implications paléocéanographiques et paléoclimatiques
Freshwater exports (sea-ice and oceanic currents) from the Arctic Ocean to the nordic seas is a critical component of the Atlantic Meridional Overturning Circulation and hence of the climatic system. Factors controling those exports are still partially unknown. An indirect way of tracing the intensity and patterns of sea-ice circulation is to trace the origin of the sediments it carries and that settle along the main drift routes towards the North Atlantic. We hence document a direct sedimentary flux that is linked to the detrital particle matrices. Another flux, this one being indirect, comes from the dissolved elements that adsorb onto particles along continental margins where sedimentary fluxes are the highest. We have extracted the authigenic (dissolved) phase from the sediment in order document the evolution of water-masses in Fram Strait since the last glacial maximum. Pb, Nd and Sr isotopic data allowed us to identify two sedimentary sources from the late glacial to the onset of the younger Dryas : canadian and western russian margins, then covered by large ice sheets. After the Younger Dryas however, sedimentary supplies originate from several sources including Greeland, Chukchi Sea and East Siberian Sea margins. The authigenic phase displays a change from 19.8 to 16.4 ka likely linked to the early deglaciation of the Eurasian ice sheet. More recently, [Epsilon]Nd values reflect a more important contribution from the Pacific on water masses exiting through Fram StraitLes flux d'eau douce, glace de mer et courants océaniques, de l'Océan Arctique vers les mers nordiques jouent un rôle critique sur l'Atlantic Meridional Overturning Circulation et donc sur le système climatique. Les facteurs contrôlant ces flux sont encore partiellement méconnus. Un moyen indirect de retracer l'intensité et les schémas de circulation de la glace de mer est de retracer l'origine des sédiments qu'elle transporte, et qui sédimentent le long des grands courants de glace et d'eau douce vers l'Atlantique Nord. Il s'agit donc de tracer un flux particulaire direct, lié à la matrice des particules détritiques. Un second flux, indirect, provient des éléments dissous dans les masses d'eau, marqués par les processus d'adsorption/désorption le long des marges où les flux particulaires terrigènes sont les plus importants. L'extraction de la phase authigène d'un signal dissous par lessivage spécifique, a permis de documenter l'évolution des masses d'eau transitant par le détroit de Fram. Les données isotopiques de Pb, Nd et Sr nous ont permis d'identifier deux sources principales de sédiments depuis le dernier maximum glaciaire jusqu'au Dryas Récent : les marges canadiennes et russes alors recouvertes par des calottes de glace. Après le Dryas Récent, les sources sédimentaires sont plus diverses avec notamment une contribution des marges groenlandaises et des mers de Chukchi et Est Sibérienne. La fraction authigène montre un changement entre ~ 19.8 et 16.4 ka probablement liée à la déglaciation de la calotte Eurasienne. Plus récemment, les valeurs [Epsilon]Nd suggèrent une influence accrue des eaux Pacifiques sur les masses d'eaux sortantes par le détroit de Fra
Radiogenic isotope (Nd, Pb, Sr) signatures of surface and sea ice-transported sediments from the Arctic Ocean under the present interglacial conditions
Under modern conditions, sediments from the large continental shelves of the Arctic Ocean are mixed by currents, incorporated into sea ice and redistributed over the Arctic Basin through the Beaufort Gyre and Trans-Polar Drift major sea-ice routes. Here, compiling data from the literature and combining them with our own data, we explore how radiogenic isotopes (Sr, Pb and Nd) from Arctic shelf surface sediment can be used to identify inland and coastal sediment sources. Based on discriminant function analyses, the use of two-isotope systematics introduces a large uncertainty (ca. 50%) that prevents unequivocal identifications of regional shelf signatures. However, when using all three isotopic systems, shelf provinces can be distinguished within a ca. 23% uncertainty only, which is mainly due to isotopic overlaps between the Canadian Arctic Archipelago and the Barents–Kara seas areas. Whereas the Canadian Arctic shelf seems mostly influenced by Mackenzie River supplies, as documented by earlier studies, a clear Lena River signature cannot be clearly identified in the Laptev–Kara seas area. The few available data on sediments collected in sea-ice rafts suggest sea ice originating mostly from the Laptev Sea area, along with non-negligible contributions from the East Siberian and Kara seas. At last, whereas a clear radiogenic identity of the Mackenzie River in sediments can be identified in the Beaufort Sea margin, isotopic signatures frommajor Russian rivers cannot be deciphered in modern Siberian margin sediments because of an intense mixing by sea ice and currents of inland and coastal supplies
Pb isotope and geochemical record of Arctic sediments
Elemental and Pb isotope measurements were performed on leachates and residues from surface sediments and two <50 cm cores (MC04 and MC16) collected along a NE-SW transect through Fram Strait. Geochemical and isotopic properties of residues from surface sediments define three distinct spatial domains within the Strait: 1) the easternmost edge of the Strait; 2) the eastern part of the Strait off the Svalbard margins; and 3) the western part of the Strait, influenced by supplies from Svalbard, the Nordic seas with possible contributions from northwestern Siberian margins, and sea ice and water outflow from the Arctic, respectively. Core MC16, in the third domain beneath the outflowing Arctic waters, spans the Last Glacial Maximum present interval. Sediments from this core were leached to obtain detrital (residues) and exchangeable (leachates) fractions. Detrital supplies to core MC16 are believed to originate mainly from melting of the overlying sea ice and thus can be used to document changes in Arctic sedimentary sources. Detrital 206Pb/204Pb and 208Pb/206Pb ratios illustrate two mixing trends, Trends A and B, corresponding to the pre- and post-Younger Dryas (YD) intervals, respectively. These trends represent binary mixtures with a common end-member (Canadian margins) and either a Siberian (Trend A) or Greenland (Trend B) margin end-member. The YD is marked by an isotopic excursion toward the Canadian end-member, suggesting a very active Beaufort Gyre possibly triggered by massive drainage of the Laurentide ice sheet. Pb isotope compositions of leachates, thought to represent the signature of the overlying water masses, define a unique linear trend coincident with Trend A. This suggests that water masses acquired their signature through exchange with particulate fluxes along the Canadian and Siberian continental margins
Propriétés géochimiques et isotopiqes des sédiments du détroit de Fram, Océan Arctique. Implications paléocéanographiques et paléoclimatiques
Les flux d'eau douce, glace de mer et courants océaniques, de l'Océan Arctique vers les mers nordiques jouent un rôle critique sur l'Atlantic Meridional Overturning Circulation et donc sur le système climatique. Les facteurs contrôlant ces flux sont encore partiellement méconnus. Un moyen indirect de retracer l'intensité et les schémas de circulation de la glace de mer est de retracer l'origine des sédiments qu'elle transporte, et qui sédimentent le long des grands courants de glace et d'eau douce vers l'Atlantique Nord. Il s'agit donc de tracer un flux particulaire direct, lié à la matrice des particules détritiques. Un second flux, indirect, provient des éléments dissous dans les masses d'eau, marqués par les processus d'adsorption/désorption le long des marges où les flux particulaires terrigènes sont les plus importants. L'extraction de la phase authigène d'un signal dissous par lessivage spécifique, a permis de documenter l'évolution des masses d'eau transitant par le détroit de Fram. Les données isotopiques de Pb, Nd et Sr nous ont permis d'identifier deux sources principales de sédiments depuis le dernier maximum glaciaire jusqu'au Dryas Récent : les marges canadiennes et russes alors recouvertes par des calottes de glace. Après le Dryas Récent, les sources sédimentaires sont plus diverses avec notamment une contribution des marges groenlandaises et des mers de Chukchi et Est Sibérienne. La fraction authigène montre un changement entre ~ 19.8 et 16.4 ka probablement liée à la déglaciation de la calotte Eurasienne. Plus récemment, les valeurs [Epsilon]Nd suggèrent une influence accrue des eaux Pacifiques sur les masses d'eaux sortantes par le détroit de FramFreshwater exports (sea-ice and oceanic currents) from the Arctic Ocean to the nordic seas is a critical component of the Atlantic Meridional Overturning Circulation and hence of the climatic system. Factors controling those exports are still partially unknown. An indirect way of tracing the intensity and patterns of sea-ice circulation is to trace the origin of the sediments it carries and that settle along the main drift routes towards the North Atlantic. We hence document a direct sedimentary flux that is linked to the detrital particle matrices. Another flux, this one being indirect, comes from the dissolved elements that adsorb onto particles along continental margins where sedimentary fluxes are the highest. We have extracted the authigenic (dissolved) phase from the sediment in order document the evolution of water-masses in Fram Strait since the last glacial maximum. Pb, Nd and Sr isotopic data allowed us to identify two sedimentary sources from the late glacial to the onset of the younger Dryas : canadian and western russian margins, then covered by large ice sheets. After the Younger Dryas however, sedimentary supplies originate from several sources including Greeland, Chukchi Sea and East Siberian Sea margins. The authigenic phase displays a change from 19.8 to 16.4 ka likely linked to the early deglaciation of the Eurasian ice sheet. More recently, [Epsilon]Nd values reflect a more important contribution from the Pacific on water masses exiting through Fram StraitMETZ-SCD (574632105) / SudocNANCY1-Bib. numérique (543959902) / SudocNANCY2-Bibliotheque electronique (543959901) / SudocNANCY-INPL-Bib. électronique (545479901) / SudocSudocFranceF
Geochemical and isotopic tracers of Arctic sea ice sources and export with special attention to the Younger Dryas interval
Radiogenic isotopes (Sr, Nd) in Ice Rafted Debris (IRD) sediments from the Lomonosov Ridge and Fram Strait Arctic areas are used to document changes in Arctic sea-ice sources and trajectories since the Last Glacial Maximum (LGM). The two records provide evidence for enhanced sea-ice production in the Beaufort Sea and its subsequent export through Fram Strait during the Younger Dryas (YD) interval. This pattern, exclusive to the YD, followed an LGM-Bølling-Allerød interval, when multiyear and/or reduced sea-ice mobility resulted in sedimentary hiatuses in the Central Arctic. Meanwhile, IRD from Svalbard-Barents ice-sheet margin source were still deposited in the Fram Strait area. The "isotopic excursion" of the YD points to enhanced sea-ice production in the Beaufort Sea, which we link to the Lake Agassiz (?)/Laurentide ice sheet drainage event through the Mackenzie route. Following this event, the Holocene depicts a 5-fold reduction in IRD rates with a shift towards prominent sea-ice production along Russian shelves. From a methodological viewpoint, we demonstrate that radiogenic isotopes must be used in a multi-proxy approach to better constrain IRD and sea-ice sources and routes. From a paleoceanographic perspective, we conclude that an Arctic freshwater/sea-ice export route should now be seen as the most likely mechanism for an AMOC reduction during the YD in accordance with more recent improved model experiment. © 2013 Elsevier Ltd.Link_to_subscribed_fulltex