Past Carbonate Preservation Events in the Deep Southeast Atlantic Ocean (Cape Basin) and Their Implications for Atlantic Overturning Dynamics and Marine Carbon Cycling

Gottschalk, Julia; Hodell, David A; Skinner, Luke C; Crowhurst, Simon J; Jaccard, Samuel L.; Charles, Christopher D.

doi:10.1029/2018pa003353

Cited by 18 publications

(9 citation statements)

References 133 publications

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“…This is supported by an agreement of our saturation index with epibenthic δ 13 C- (Skinner et al, 2007;Margari et al, 2010) and SST changes at the Iberian Margin (Martrat et al, 2007; Fig. 7), the high-resolution 231 Pa/ 230 Th record from Bermuda Rise (Henry et al, 2016) and a carbonate saturation record from the deep Cape Basin (Gottschalk et al, 2018), which reflect similar AMOC changes in the Atlantic basin. This agreement corroborates a strong causal link between bottom water [O 2 ] changes in the deep South Atlantic and end-member changes of southern-sourced water masses related to variations in air-sea gas exchange-and/or the ventilation rate, which may be linked to variations in the southward extent of NADW.…”

Section: Changes In Deep Southsupporting

confidence: 81%

Southern Ocean link between changes in atmospheric CO2 levels and northern-hemisphere climate anomalies during the last two glacial periods

Gottschalk

Skinner

Jaccard

et al. 2020

Quaternary Science Reviews

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Section: Changes In Deep Southsupporting

confidence: 81%

Southern Ocean link between changes in atmospheric CO2 levels and northern-hemisphere climate anomalies during the last two glacial periods

Gottschalk

Skinner

Jaccard

et al. 2020

Quaternary Science Reviews

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“…Below ~2.5 km, LGM North Atlantic [CO3 2-] values were up to ~20 mol/kg lower than today, consistent with greater mixing/advection of low-[CO3 2-] Glacial Antarctic Bottom Waters (GAABW) and/or increased respiration in the glacial ocean 1,2,19,20 . The boundary of ~2.5 km delineated by LGM upper and lower water masses is consistent with that found from other proxies ( 13 C, Cd/Ca, and Nd) and model results 1-3,19,21,22 . In the South Atlantic, deep-water [CO3 2-] in the 5 studied cores from ~3-4 km water depth are lower by ~20 mol/kg during the LGM than the Holocene, consistent with qualitative [CO3 2-] proxies from the same cores [23][24][25] ( Supplementary Fig. 2).…”

Section: First Meridional [Co3 2-] Transect For the Lgm Deep Atlanticsupporting

confidence: 77%

“…shows slightly higher deep-water [CO3 2-] values during the LGM than the Holocene, supported by multiple benthic B/Ca measurements in this core and qualitative proxies including %CaCO3 and foraminiferal fragmentation data for several South Atlantic cores at similar water depths 15,23,24 ( Supplementary Fig. 3).…”

Section: First Meridional [Co3 2-] Transect For the Lgm Deep Atlanticsupporting

confidence: 67%

Last glacial atmospheric CO2 decline due to widespread Pacific deep-water expansion

Menviel

Jin

et al. 2020

Nat. Geosci.

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Although critical for global climate and the carbon cycle, the nature of past ocean circulation changes remains elusive. Based on deep-water carbonate ion ([CO3 2-]) reconstructions for wide locations, we discover a low-[CO3 2-] water mass in the South Atlantic at ~3-4 km (extending northward up to ~20°S) during the Last Glacial Maximum. Multiple proxies suggest that this low-[CO3 2-] signal likely reflects an extensive expansion of carbon-rich Pacific deep waters, revealing an ocean circulation scheme different from the long-held view for the glacial deep Atlantic. Comparison of high-resolution [CO3 2-] records from different water depths in the South Atlantic indicates that this expansion occurred between ~38 and ~28 thousand years ago. We infer that the associated carbon sequestration might have contributed critically to the contemporary ~20 ppm atmospheric CO2 decline and thereby helped pushing the global climate to the glacial maximum. Ocean circulation and the carbon cycle are intricately linked, and ocean circulation reconstructions can therefore provide important insights into mechanisms for past atmospheric CO2 changes. Ocean circulation in the deep Atlantic Ocean (>~2.5 km) during the Last Glacial Maximum (LGM; 18-22 ka) is traditionally viewed to follow a mixing model between northernand southern-sourced deep waters produced in the polar Atlantic, without much need to involve waters from other oceans 1-4. Using this long-held ocean circulation model, however, it is difficult to explain the observed older radiocarbon ages (14 C ages) and more radiogenic neodymium isotopic (Nd) signatures at ~3.8 km than at ~5 km in the LGM South Atlantic 5,6 (Fig. 1). Burke et al. 7 showed that sluggish recirculation of southern-sourced waters combined with reduced mixing with 14 C-rich northern-sourced waters can contribute to the old 14 C ages at ~3.

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“…The results demonstrate that ocean sediments and the weathering-burial cycle are an integral part of the Earth system playing a fundamental role on glacialinterglacial timescales. The Bern3D EMIC features a three-dimensional geostrophic ocean (Müller et al, 2006;Edwards et al, 1998) with an isopycnal diffusion scheme and Gent-McWilliams parameterization for eddy-induced transport (Griffies, 1998). The model includes a thermodynamic sea-ice component coupled to a single-layer energy-moisture balance atmosphere (Ritz et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

Low terrestrial carbon storage at the Last Glacial Maximum: constraints from multi-proxy data

et al. 2019

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Abstract. Past changes in the inventory of carbon stored in vegetation and soils remain uncertain. Earlier studies inferred the increase in the land carbon inventory (Δland) between the Last Glacial Maximum (LGM) and the preindustrial period (PI) based on marine and atmospheric stable carbon isotope reconstructions, with recent estimates yielding 300–400 GtC. Surprisingly, however, earlier studies considered a mass balance for the ocean–atmosphere–land biosphere system only. Notably, these studies neglect carbon exchange with marine sediments, weathering–burial flux imbalances, and the influence of the transient deglacial reorganization on the isotopic budgets. We show this simplification to significantly reduce Δland in simulations using the Bern3D Earth System Model of Intermediate Complexity v.2.0s. We constrain Δland to ∼850 GtC (median estimate; 450 to 1250 GtC ±1SD) by using reconstructed changes in atmospheric δ13C, marine δ13C, deep Pacific carbonate ion concentration, and atmospheric CO2 as observational targets in a Monte Carlo ensemble with half a million members. It is highly unlikely that the land carbon inventory was larger at LGM than PI. Sensitivities of the target variables to changes in individual deglacial carbon cycle processes are established from transient factorial simulations with the Bern3D model. These are used in the Monte Carlo ensemble and provide forcing–response relationships for future model–model and model–data comparisons. Our study demonstrates the importance of ocean–sediment interactions and burial as well as weathering fluxes involving marine organic matter to explain deglacial change and suggests a major upward revision of earlier isotope-based estimates of Δland.

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Past Carbonate Preservation Events in the Deep Southeast Atlantic Ocean (Cape Basin) and Their Implications for Atlantic Overturning Dynamics and Marine Carbon Cycling

Cited by 18 publications

References 133 publications

Southern Ocean link between changes in atmospheric CO2 levels and northern-hemisphere climate anomalies during the last two glacial periods

Southern Ocean link between changes in atmospheric CO2 levels and northern-hemisphere climate anomalies during the last two glacial periods

Last glacial atmospheric CO2 decline due to widespread Pacific deep-water expansion

Low terrestrial carbon storage at the Last Glacial Maximum: constraints from multi-proxy data

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