On the potential role of marine calcifiers in glacial‐interglacial dynamics

Omta, Anne Willem; Voorn, G.A.K. van; Rickaby, Rosalind E. M.; Follows, Michael J.

doi:10.1002/gbc.20060

Cited by 28 publications

(55 citation statements)

References 127 publications

(171 reference statements)

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“…10 Several mechanisms that have been proposed to explain low glacial atmospheric CO 2 concentrations involve decreased CaCO 3 burial (Vecsei and Berger, 2004;Hain et al, 2014a), which would have raised ALK and thereby increased CO 2 solubility. One of these calls on changes in ocean circulation (Boyle, 1988;Jaccard et al, 2009) or biological production (Archer et al, 2000;Omta et al, 2013) to have raised the DIC in the deep ocean and therefore have lowered deep ocean CO 3 2-, requiring the ocean to compensate by dissolving CaCO 3 until the alkalinity was raised sufficiently to restore CO 3 2-…”

Section: Introductionmentioning

confidence: 99%

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Cartapanis¹,

Galbraith²,

Bianchi³

et al. 2018

Preprint

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Abstract. Although long assumed that the glacial-interglacial cycles of atmospheric CO 2 occurred despite a constant 'active' carbon inventory, there are signs that the geological CO 2 supply rates varied. However, changes of the carbon inventory cannot be assessed without constraining the removal rates from the system, which mainly occurs in marine sediments. Here, 15we present the first global reconstruction of carbon and alkalinity burial in deep-sea sediments over the last glacial cycle.Although subject to large uncertainties, the reconstruction provides a first order constraint on changes in carbon and alkalinity inventories over the last glacial cycle. The results suggest that reduced burial of carbonate in the Atlantic Ocean was not entirely compensated by the increased burial in the Pacific basin during the last glacial period. The burial-driven inventory variations are likely to have significantly altered the δ 13 C of the ocean-atmosphere carbon, as well as the DIC and 20 alkalinity budget, confirming that the active carbon inventory was a dynamic, interactive component of the glacial cycles.Clim. Past Discuss., https://doi

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Section: Introductionmentioning

confidence: 99%

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Cartapanis¹,

Galbraith²,

Bianchi³

et al. 2018

Preprint

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“…As in Omta et al (2013), we therefore apply a periodic forcing to the reaction rate parameter k which directly impacts the calcifier population growth rate:…”

Section: Modelmentioning

confidence: 99%

“…We use the calcifier-alkalinity model that has been described and discussed in detail in Omta et al (2013); the model code, including brief instructions, has been attached as online Auxiliary Material. In its simplest version, the model consists of two differential equations for ocean alkalinity A and a calcifier population C (variables and parameter values listed in Table 1): Alkalinity A is added to the ocean at a fixed rate I through river runoff resulting from weathering and consumed by a population of calcifiers C, growing at an effective rate kA and sedimenting at a rate M. The autocatalytic process described in the set of Eq.…”

Section: Modelmentioning

confidence: 99%

“…Rather, we argue that such changes are an inherent feature of sawtooth-spike oscillations, which the glacial-interglacial cycles resemble. We use the previously developed calcifier-alkalinity model (Omta et al 2013) as an illustrative example of a system exhibiting sawtooth-spike behavior. Within the context of this model, the rapid deglaciations and the different glacial periodicities need to be related to atmospheric CO 2 .…”

Section: Introductionmentioning

confidence: 99%

“…In Omta et al (2013), simulations were performed with the most idealized version of the calcifier-alkalinity model under a 20-kyr sinusoidal forcing with relative amplitude α = 0.0025 (that is, variations in the parameter k were a factor 0.0025, or 0.25 % around the mean). The system exhibited cycles with the same periodicity as the forcing.…”

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confidence: 99%

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Inherent characteristics of sawtooth cycles can explain different glacial periodicities

Omta

Kooi²,

Voorn

et al. 2015

Clim Dyn

Self Cite

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change, while the forcing periodicity remains fixed, due to either random variations or different frequency components of the orbital forcing. Two key relationships stand out as predictions to be tested against observations: (1) the amplitude and the periodicity of the cycles are approximately linearly proportional to each other, a relationship that is also found in the δ 18 O temperature proxy. (2) The magnitude of the spikes increases with increasing periodicity and amplitude of the sawtooth. This prediction could be used to identify one or more currently hidden spiking variables driving the glacial-interglacial transitions. Essentially, the quest would be for any proxy record, concurrent with a dynamical model prediction, that exhibits deglacial spikes which increase at times when the amplitude/periodicity of the glacial cycles increases. In the specific context of our calcifier-alkalinity mechanism, the records of interest would be calcifier productivity and calcite accumulation. We believe that such a falsifiable hypothesis should provide a strong motivation for the collection of further records.

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Complementary constraints from carbon (¹³C) and nitrogen (¹⁵N) isotopes on the glacial ocean's soft‐tissue biological pump

Schmittner

Somes

2016

Paleoceanography

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A three-dimensional, process-based model of the ocean's carbon and nitrogen cycles, including 13 C and 15 N isotopes, is used to explore effects of idealized changes in the soft-tissue biological pump. Results are presented from one preindustrial control run (piCtrl) and six simulations of the Last Glacial Maximum (LGM) with increasing values of the spatially constant maximum phytoplankton growth rate μ max , which accelerates biological nutrient utilization mimicking iron fertilization. The default LGM simulation, without increasing μ max and with a shallower and weaker Atlantic Meridional Overturning Circulation and increased sea ice cover, leads to 280 Pg more respired organic carbon (C org ) storage in the deep ocean with respect to piCtrl. Dissolved oxygen concentrations in the colder glacial thermocline increase, which reduces water column denitrification and, with delay, nitrogen fixation, thus increasing the ocean's fixed nitrogen inventory and decreasing δ 15 N NO3 almost everywhere. This simulation already fits sediment reconstructions of carbon and nitrogen isotopes relatively well, but it overestimates deep ocean δ 13 C DIC and underestimates δ 15 N NO3 at high latitudes. Increasing μ max enhances C org and lowers deep ocean δ 13 C DIC , improving the agreement with sediment data. In the model's Antarctic and North Pacific Oceans modest increases in μ max result in higher δ 15 N NO3 due to enhanced local nutrient utilization, improving the agreement with reconstructions there. Models with moderately increased μ max fit both isotope data best, whereas large increases in nutrient utilization are inconsistent with nitrogen isotopes although they still fit the carbon isotopes reasonably well. The best fitting models reproduce major features of the glacial δ 13 C DIC , δ 15 N, and oxygen reconstructions while simulating increased C org by 510-670 Pg compared with the preindustrial ocean. These results are consistent with the idea that the soft-tissue pump was more efficient during the LGM. Both circulation and biological nutrient utilization could contribute. However, these conclusions are preliminary given our idealized experiments, which do not consider changes in benthic denitrification and spatially inhomogenous changes in aeolian iron fluxes. The analysis illustrates interactions between the carbon and nitrogen cycles as well as the complementary constraints provided by their isotopes. Whereas carbon isotopes are sensitive to circulation changes and indicate well the three-dimensional C org distribution, nitrogen isotopes are more sensitive to biological nutrient utilization.

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On the potential role of marine calcifiers in glacial‐interglacial dynamics

Cited by 28 publications

References 127 publications

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Inherent characteristics of sawtooth cycles can explain different glacial periodicities

Complementary constraints from carbon (¹³C) and nitrogen (¹⁵N) isotopes on the glacial ocean's soft‐tissue biological pump

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On the potential role of marine calcifiers in glacial‐interglacial dynamics

Cited by 28 publications

References 127 publications

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Carbon burial in deep-sea sediment and implications for oceanic inventories of carbon and alkalinity over the last glacial cycle

Inherent characteristics of sawtooth cycles can explain different glacial periodicities

Complementary constraints from carbon (13C) and nitrogen (15N) isotopes on the glacial ocean's soft‐tissue biological pump

Contact Info

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Resources

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Complementary constraints from carbon (¹³C) and nitrogen (¹⁵N) isotopes on the glacial ocean's soft‐tissue biological pump