Radiocarbon constraints on the glacial ocean circulation and its impact on atmospheric CO2

Skinner, Luke C; Primeau, François; Freeman, Erika C.; Fuente, Maria de la; Goodwin, Philip; Gottschalk, Julia; Huang, Enqing; McCave, I Nick; Noble, Taryn L; Scrivner, A. E.

doi:10.1038/ncomms16010

Cited by 127 publications

(198 citation statements)

References 61 publications

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“…Recent studies have inferred the presence of 14 C age maxima at water depths of 3,500–4,500 m in the deep Atlantic during the LGM (Burke et al, ; Keigwin & Swift, ; Skinner et al, ). Age extrema at these depths cannot be captured by the ventilation model used in this study, as this model represents the entire Atlantic below 1,500 m with a single box.…”

Section: Sensitivity To Data and Model Assumptionsmentioning

confidence: 99%

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

Zhao

Marchal

Keigwin

et al. 2018

Paleoceanog and Paleoclimatol

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We present a synthesis of 1,361 deep‐sea radiocarbon data spanning the past 40 kyr and computed (for 14C‐dated records) from the same calibration to atmospheric 14C. The most notable feature in our compilation is a long‐term Δ14C decline in deep oceanic basins over the past 25 kyr. The Δ14C decline mirrors the drop in reconstructed atmospheric Δ14C, suggesting that it may reflect a decrease in global 14C inventory rather than a redistribution of 14C among different reservoirs. Motivated by this observation, we explore the extent to which the deep water Δ14C data jointly require changes in basin‐scale ventilation during the last deglaciation, based on the fit of a 16‐box model of modern ocean ventilation to the deep water Δ14C records. We find that the fit residuals can largely be explained by data uncertainties and that the surface water Δ14C values producing the fit are within the bounds provided by contemporaneous values of atmospheric and deep water Δ14C. On the other hand, some of the surface Δ14C values in the northern North Atlantic and the Southern Ocean deviate from the values expected from atmospheric 14CO2 and CO2 concentrations during the Heinrich Stadial 1 and the Bølling‐Allerød. The possibility that deep water Δ14C records reflect some combination of changes in deep circulation and surface water reservoir ages cannot be ruled out and will need to be investigated with a more complete model.

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Section: Sensitivity To Data and Model Assumptionsmentioning

confidence: 99%

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

Zhao

Marchal

Keigwin

et al. 2018

Paleoceanog and Paleoclimatol

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“…More recently, radiocarbon observations have been used to infer the ventilation age of deep waters using inverse models (Gebbie & Huybers, ; Khatiwala et al, ) and tracer‐only inversions (Holzer et al, , ) and to constrain rates of ocean circulation and ventilation in global ocean inverse models (DeVries & Primeau, ; Schlitzer, ). Measurements of the Δ 14 C of fossil foraminifera have also been used to constrain the circulation of the ocean during the last glacial maximum (Skinner et al, ) and the most recent deglaciation (Tschumi et al, ). (The abundance of 14 C is usually expressed relative to the abundance of the more common 12 C isotope and in turn normalized to the isotope ratio of the preindustrial atmosphere and corrected for biological fractionation effects.…”

Section: Introductionmentioning

confidence: 99%

Radiocarbon and Helium Isotope Constraints on Deep Ocean Ventilation and Mantle‐³He Sources

DeVries

Holzer

2019

JGR Oceans

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Radiocarbon (Δ14C) and helium isotopes (δ3He) have long been used to constrain the ocean's ventilation rates and to trace regional deep ocean circulation pathways, but they have not been fully exploited together to constrain the deep circulation in global models. Here we assimilate Δ14C and δ3He measurements into a global ocean circulation inverse model (OCIM) to jointly constrain the deep ocean circulation and the rate of mantle‐helium injection at seafloor spreading ridges. We find that the new version of the inverse model (OCIM2) matches the observed Δ14C and δ3He distributions much better than a previous version (OCIM1) that assimilated objectively mapped Δ14C but not δ3He. OCIM2 features faster‐ventilated bottom waters and slower‐ventilated intermediate‐depth waters in the Pacific and Indian Oceans. The mean time since last ventilation (ideal mean age) in Pacific bottom waters is up to 150 years younger, while middepth Pacific waters are up to several hundred years older. The δ3He constraints are shown to be important for estimates of the mean time to next ventilation in the Pacific Ocean. The δ3He constraints also favor jet‐like currents in the deep equatorial Pacific to capture realistic westward propagating helium plumes emanating from the East Pacific Rise. The globally integrated mantle‐helium source is 585–672 mol/year, compared to 400–1,000 mol/year from previous estimates. The major regional difference occurs in the Southern Ocean, where the OCIM2 mantle‐helium source is up to threefold smaller than estimates based on ridge spreading rates.

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“…Processes that potentially explain atmospheric CO 2 change during glacial cycles include the efficiency of the biological pump (Martínez-Garcia et al, 2009;Galbraith and Jaccard, 2015), circulation changes (Ferrari et al, 2014;Schmittner and Lund, 2015;Lacerra et al, 2017;Menviel et al, 2017;Sikes et al, 2017;Wagner and Hendy, 2017), or a combination of multiple processes (Bauska et al, 2016;Skinner et al, 2017). Different processes could influence the carbon cycle on different timescales (Bauska et al, 2016;Kohfeld and Chase, 2017) and/or in different regions (e.g., Gu et al, 2017) and complicate interpretations of which processes are most responsible for atmospheric CO 2 change.…”

Section: Deep Pacific and Global Mean δ 13 Cmentioning

confidence: 99%

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

Peterson

Lisiecki

2018

Clim. Past

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Abstract. We present a compilation of 127 time series δ 13 C records from Cibicides wuellerstorfi spanning the last deglaciation (20-6 ka) which is well-suited for reconstructing large-scale carbon cycle changes, especially for comparison with isotope-enabled carbon cycle models. The age models for the δ 13 C records are derived from regional planktic radiocarbon compilations . The δ 13 C records were stacked in nine different regions and then combined using volume-weighted averages to create intermediate, deep, and global δ 13 C stacks. These benthic δ 13 C stacks are used to reconstruct changes in the size of the terrestrial biosphere and deep ocean carbon storage. The timing of change in global mean δ 13 C is interpreted to indicate terrestrial biosphere expansion from 19-6 ka. The δ 13 C gradient between the intermediate and deep ocean, which we interpret as a proxy for deep ocean carbon storage, matches the pattern of atmospheric CO 2 change observed in ice core records. The presence of signals associated with the terrestrial biosphere and atmospheric CO 2 indicates that the compiled δ 13 C records have sufficient spatial coverage and time resolution to accurately reconstruct large-scale carbon cycle changes during the glacial termination.

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Radiocarbon constraints on the glacial ocean circulation and its impact on atmospheric CO2

Cited by 127 publications

References 61 publications

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

Radiocarbon and Helium Isotope Constraints on Deep Ocean Ventilation and Mantle‐³He Sources

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

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Radiocarbon constraints on the glacial ocean circulation and its impact on atmospheric CO2

Cited by 127 publications

References 61 publications

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

A Synthesis of Deglacial Deep‐Sea Radiocarbon Records and Their (In)Consistency With Modern Ocean Ventilation

Radiocarbon and Helium Isotope Constraints on Deep Ocean Ventilation and Mantle‐3He Sources

Deglacial carbon cycle changes observed in a compilation of 127 benthic &lt;i&gt;δ&lt;/i&gt;&lt;sup&gt;13&lt;/sup&gt;C time series (20–6 ka)

Contact Info

Product

Resources

About

Radiocarbon and Helium Isotope Constraints on Deep Ocean Ventilation and Mantle‐³He Sources

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)