Your search keyword '"Mulitza, S."' showing total 9 results

1. Stagnant North Atlantic Deep Water Heat Uptake With Reduced Atlantic Meridional Overturning Circulation During the Last Deglaciation.

Author

Barragán‐Montilla, S., Mulitza, S., Johnstone, H. J. H., and Pälike, H.

Subjects

ATLANTIC meridional overturning circulation, OCEAN circulation, YOUNGER Dryas, BOTTOM water (Oceanography), HEAT storage, GLACIAL melting, MINE ventilation

Abstract

Atlantic Meridional Overturning Circulation (AMOC) plays a major role in the climate system by modulating the depth and rate of oceanic heat storage. Some climate simulations suggest that reduced AMOC decreases bottom water ventilation and that the heat absorbed by the ocean starts to mix downwards, warming Atlantic intermediate waters. This has been corroborated for the western North Atlantic by benthic foraminifera geochemical records from periods of reduced AMOC during the last deglaciation. However, the deep‐water response remains poorly constrained, and the lack of direct paleotemperature reconstructions limits our understanding about the effects of reduced circulation on ocean heat uptake. We present a new reconstruction of bottom water temperatures from core GeoB9508‐5 (2,384 m water depth, 15°29.90°N/17°56.88°W) off the northwestern African Margin. Our paleotemperature record, based on Uvigerina spp. Mg/Ca, shows two episodes of intense transient deep water warming in times of decreasing overturning circulation, followed by long periods of heat uptake stagnation. First, during AMOC slowdown in the Heinrich stadial 1, when paleotemperatures of ∼2°C persisted for ∼5.4 Kyr coincident with the weakest stage of AMOC; and second in the Younger Dryas, when bottom water temperatures >4°C lasted ∼2.5 Kyr during a less intense AMOC decline. This suggests a stagnation of deep‐water heat uptake in the deep NE Atlantic possibly linked to a reduced downward advection of heat during times of a reduced AMOC, supporting the hypothesis that AMOC strength sets the depth of oceanic heat storage in the North Atlantic. Plain Language Summary: Anthropogenic activity affects earth‐atmosphere energy balance enhancing climate change in the last decades. The ocean plays a key role in this balance, by taking up to 90% of the excess heat from the atmosphere and redistributing it globally though the Atlantic Meridional Overturning Circulation (AMOC). For the 21st century, a possible 34%–45% AMOC reduction has been hypothesized, raising concern on its effects on ocean heat uptake and climate change. To contribute to the understanding of these possible effects, we reconstructed bottom water temperatures changes for eastern North Atlantic deep waters over the last 46,000 years, including two periods with a significantly reduced AMOC: (a) Heinrich Stadial 1 (18,200–14,900 years ago) and (b) the Younger Dryas (12,800–11,700 years ago). Our results suggest that with a weak AMOC, Atlantic intermediate waters warm as ventilation decreases, at the same time this heat stops being transferred to the deep eastern North Atlantic for thousands of years. The implications of these processes for global warming still need to be investigated. Key Points: Intense North Atlantic Deep‐Water (NADW) warming at the beginning of Heinrich Stadial 1 (HS1) and the Younger Dryas (YD)With a weak Atlantic Meridional Overturning Circulation during HS1 and the YD deep water temperature remained stable in poorly ventilated bottom watersWeaker HS1 and YD NADW formation, may reduce heat dissipation into the deep Atlantic [ABSTRACT FROM AUTHOR]

Published

2023

2. Negligible Quantities of Particulate Low‐Temperature Pyrogenic Carbon Reach the Atlantic Ocean via the Amazon River.

Author

Häggi, C., Hopmans, E. C., Schefuß, E., Sawakuchi, A. O., Schreuder, L. T., Bertassoli, D. J., Chiessi, C. M., Mulitza, S., Sawakuchi, H. O., Baker, P. A., and Schouten, S.

Subjects

MARINE sediments, CARBONACEOUS aerosols, COLLOIDAL carbon, SUSPENDED sediments, RIVER sediments, BIOMASS burning, RIVER channels

Abstract

Particulate pyrogenic carbon (PyC) transported by rivers and aerosols, and deposited in marine sediments, is an important part of the carbon cycle. The chemical composition of PyC is temperature dependent and levoglucosan is a source‐specific burning marker used to trace low‐temperature PyC. Levoglucosan associated to particulate material has been shown to be preserved during riverine transport and marine deposition in high‐ and mid‐latitudes, but it is yet unknown if this is also the case for (sub)tropical areas, where 90% of global PyC is produced. Here, we investigate transport and deposition of levoglucosan in suspended and riverbed sediments from the Amazon River system and adjacent marine deposition areas. We show that the Amazon River exports negligible amounts of levoglucosan and that concentrations in sediments from the main Amazon tributaries are not related to long‐term mean catchment‐wide fire activity. Levoglucosan concentrations in marine sediments offshore the Amazon Estuary are positively correlated to total organic content regardless of terrestrial or marine origin, supporting the notion that association of suspended or dissolved PyC to biogenic particles is critical in the preservation of PyC. We estimate that 0.5–10 × 106 g yr−1 of levoglucosan is exported by the Amazon River. This represents only 0.5–10 ppm of the total exported PyC and thereby an insignificant fraction, indicating that riverine derived levoglucosan and low‐temperature PyC in the tropics are almost completely degraded before deposition. Hence, we suggest caution in using levoglucosan as tracer for past fire activity in tropical settings near rivers. Plain Language Summary: During plant organic matter burning, most of the carbon is emitted to the atmosphere as CO2, but a fraction is retained as pyrogenic biomass. The chemical composition of pyrogenic biomass depends on fire temperature and allows to differentiate between high and low‐temperature pyrogenic biomass. Here, we analyzed if low‐temperature pyrogenic biomass is preserved during transport in the Amazon River and deposited in western tropical Atlantic sediments. We found that only negligible amounts of low‐temperature pyrogenic biomass reach the Atlantic through riverine transport. While most pyrogenic carbon (PyC) originates in the tropics, our study suggests that only an insignificant fraction of low‐temperature PyC is permanently stored in marine sediments, where it would be removed from the short‐term carbon cycle. Key Points: Only negligible amounts of the source‐specific low‐temperature biomass burning tracer levoglucosan are exported by the Amazon River systemMarine sediment levoglucosan yields are controlled by organic carbon content regardless of marine or terrestrial source of organic matterDust and river derived levoglucosan escape burial in the tropical Atlantic, despite the dominant tropical source of pyrogenic carbon [ABSTRACT FROM AUTHOR]

Published

2021

3. Mid‐ to Late Holocene Contraction of the Intertropical Convergence Zone Over Northeastern South America.

Author

Chiessi, C. M., Mulitza, S., Taniguchi, N. K., Prange, M., Campos, M. C., Häggi, C., Schefuß, E., Pinho, T. M. L., Frederichs, T., Portilho‐Ramos, R. C., Sousa, S. H. M., Crivellari, S., and Cruz, F. W.

Subjects

INTERTROPICAL convergence zone, HOLOCENE Epoch, WALKER circulation, WATER security, MARINE sediments

Abstract

Modern precipitation over northeastern (NE) South America is strongly controlled by the seasonal meridional migration of the Intertropical Convergence Zone (ITCZ). Ample evidence from the Northern Hemisphere suggests a mid‐ to late Holocene southward migration of the ITCZ. Such a shift would be expected to increase precipitation over semi‐arid northern NE Brazil (Southern Hemisphere). However, the most robust precipitation record from northern NE Brazil shows a drying trend throughout the Holocene. Here, we address this issue presenting a high‐temporal resolution reconstruction of precipitation over northern NE Brazil based on data from a marine sediment core, together with analyses of mid‐ and late Holocene simulations performed with the fully coupled climate model FGOALS‐s2. Both, our data and the climate model simulations show a decrease in precipitation over northern NE Brazil from the mid‐ to the late Holocene. The model outputs further indicate a latitudinal contraction of the seasonal migration range of the ITCZ that, together with an intensification of the regional Walker circulation, were responsible for the mid‐ to late Holocene changes in precipitation over NE South America. Our results reconcile apparently conflicting precipitation records and climate mechanisms used to explain changes in precipitation over NE South America. Plain Language Summary: The tropical rainbelt impacts food and water security for 1 billion people. Knowing its dynamics is of utmost importance. The suggestion of a southward migration of the tropical rainbelt through the Holocene (last 11,700 years) has influenced paleoclimatology for two decades. However, most of the available evidence supporting this suggestion comes from tropical Northern Hemisphere precipitation reconstructions like northernmost South America. They systematically show a decrease in precipitation through the Holocene. In the tropical Southern Hemisphere like northeastern Brazil, at the opposite side of the tropical rainbelt, precipitation reconstructions are, however, rare. We reconstructed mid‐ to late Holocene (last 5,200 years) changes in precipitation over northeastern Brazil (tropical Southern Hemisphere), where modern precipitation is associated with the southern border of the tropical rainbelt. We analyzed three independent indicators of changes in precipitation recorded in marine sediments collected off northeastern Brazil. All indicators suggest a decrease in precipitation over northeastern Brazil from the mid‐ to the late Holocene. Together with climate model simulations, our results indicate a latitudinal contraction of the tropical rainbelt. A Holocene contraction of the rainbelt, in contrast to a southward migration, reconciles apparently conflicting precipitation reconstructions and provides valuable insights into the dynamics of the tropical rainbelt. Key Points: Precipitation over northern northeastern Brazil decreased from the mid‐ to the late HoloceneThe meridional migration range of the Intertropical Convergence Zone contracted from the mid‐ to the late HoloceneTogether with the intensification of the regional Walker circulation, our results reconcile previously conflicting records [ABSTRACT FROM AUTHOR]

Published

2021

4. Water Mass Versus Sea Level Effects on Benthic Foraminiferal Oxygen Isotope Ratios in the Atlantic Ocean During the LGM.

Author

Völpel, R., Mulitza, S., Paul, A., Lynch‐Stieglitz, J., and Schulz, M.

Subjects

INTERGLACIALS, OXYGEN isotopes, ATMOSPHERIC temperature, WATER masses, WATER depth, SEA level

Abstract

Depth transects of benthic foraminiferal oxygen isotopes from the Atlantic Ocean show that glacial‐interglacial changes are larger at deep (> ~2,000 m) than at intermediate water levels. Our model results suggest that the smaller changes in the upper 1,000 m of the water column are a result of the glacial sea level lowering of about 120 m, leading to warmer temperatures of around 1 °C and hence a smaller glacial‐interglacial stable oxygen isotope difference. In contrast, a shoaling of the water mass boundary to ~2,000‐m water depth between the northern and southern source waters is caused by the expansion of a cold (close to the freezing point) southern source water in the abyssal ocean, increasing the oxygen isotope values of benthic foraminifera from the Last Glacial Maximum in the deep Atlantic. These two effects explain the different amplitudes of glacial‐interglacial stable oxygen isotope differences in the upper and deeper water column of the Atlantic Ocean. Key Points: Benthic δ18O glacial‐interglacial changes off north West Africa and in the west Atlantic Ocean were investigated with an ocean modelModel results suggest smaller glacial‐interglacial δ18O differences around the thermocline layer due to glacial sea level loweringThe expansion of cold southern source water during the LGM led to larger glacial‐interglacial δ18O differences in the deep Atlantic Ocean [ABSTRACT FROM AUTHOR]

Published

2019

5. Millennial‐ to Orbital‐Scale Responses of Western Equatorial Atlantic Thermocline Depth to Changes in the Trade Wind System Since the Last Interglacial.

Author

Venancio, I. M., Mulitza, S., Govin, A., Santos, T. P., Lessa, D. O., Albuquerque, A. L. S., Chiessi, C. M., Tiedemann, R., Vahlenkamp, M., Bickert, T., and Schulz, M.

Subjects

THERMOCLINES (Oceanography), CLIMATE change, TRADE winds, INTERGLACIALS, STABLE isotopes

Abstract

Surface ocean circulation in the western equatorial Atlantic is mainly wind driven and plays a major role for the transport of warm waters to the North Atlantic. Past changes in the strength and direction of the trade winds are well documented, but the response of the western equatorial Atlantic circulation and water column structure to these changes is unclear. Here we used the difference between the stable isotopic oxygen composition of two species of planktonic foraminifera (Globigerinoides ruber white and Neogloboquadrina dutertrei) from two sediment cores collected off northeastern Brazil to investigate millennial‐ and orbital‐scale changes in upper ocean stratification since the Last Interglacial. Our records indicate enhanced upper ocean stratification during several Heinrich stadials, partly due to a shoaling of the thermocline, which was linked to a decrease in the strength of southeast trades winds. In addition, we show that a decrease in wind zonality induced by increases in Northern Hemisphere low‐latitude summer insolation causes a shoaling of the thermocline in the western equatorial Atlantic. These ocean‐atmosphere changes contributed to a reduction in the cross‐equatorial transport of warm waters, particularly during Heinrich stadials and Marine Isotope Stage 4. Key Points: Changes in western equatorial Atlantic thermocline depth were recorded on millennial and orbital time scalesShoaling of the thermocline during Heinrich stadials was associated with weak southeast trade windsShoaling of the thermocline during periods of low‐latitude boreal summer insolation maxima occurred due to decreased wind zonality [ABSTRACT FROM AUTHOR]

Published

2018

6. Variability in mid-depth ventilation of the western Atlantic Ocean during the last deglaciation.

Author

Voigt, I., Cruz, A. P. S., Mulitza, S., Chiessi, C. M., Mackensen, A., Lippold, J., Antz, B., Zabel, M., Zhang, Y., Barbosa, C. F., and Tisserand, A. A.

Published

2017

7. Modeling the seasonal distribution of planktonic foraminifera during the Last Glacial Maximum.

Author

Fraile, I., Schulz, M., Mulitza, S., Merkel, U., Prange, M., and Paul, A.

Published

2009

8. Millennial-scale northwest African droughts related to Heinrich events and Dansgaard-Oeschger cycles: Evidence in marine sediments from offshore Senegal.

Author

Itambi, A. C., von Dobeneck, T., Mulitza, S., Bickert, T., and Heslop, D.

Published

2009

9. Sea surface temperatures in the equatorial and South Atlantic Ocean during the Last Glacial Maximum (23-19 ka).

Author

Niebler, H.-S., Arz, H. W., Donner, B., Mulitza, S., Pätzold, J., and Wefer, G.

Published

2003