The Role of External Inputs and Internal Cycling in Shaping the Global Ocean Cobalt Distribution: Insights From the First Cobalt Biogeochemical Model

Tagliabue, Alessandro; Hawco, Nicholas J.; Bundy, Randelle M.; Landing, William M.; Milne, Angela; Morton, Peter L.; Saito, Mak A.

doi:10.1002/2017gb005830

Cited by 47 publications

(82 citation statements)

References 91 publications

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“…Therefore, long-term sources of the dissolved Co pool in the Gyre most likely originate from coastal fluxes and upwelling, which is consistent with recent global modeling results (Hawco et al, 2016;Saito et al, 2004;Sanial et al, 2018;Tagliabue et al, 2018). The dust input to the Gyre ranges from 0.004 to 0.01 nmol·m À2 ·day À1 which is, at most, 0.8% of export if the station with the lowest particulate Co flux is used.…”

Section: Particulate CD Cyclingsupporting

confidence: 87%

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Black

Lam

Lee

et al. 2019

Global Biogeochemical Cycles

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Better constraints on the magnitude of particulate export and the residence times of trace elements are required to understand marine food web dynamics, track the transport of anthropogenic trace metals in the ocean, and improve global climate models. While prior studies have been successful in constructing basin‐scale budgets of elements like carbon in the upper ocean, the cycling of particulate trace metals is poorly understood. The 238U‐234Th method is used here with data from the GP‐16 GEOTRACES transect to investigate the upper ocean processes controlling the particulate export of cadmium, cobalt, and manganese in the southeastern Pacific. Patterns in the flux data indicated that particulate cadmium and cobalt behave similarly to particulate phosphorus and organic carbon, with the highest export in the productive coastal region and decreasing flux with depth due to remineralization. The export of manganese was influenced by redox conditions at the low oxygen coastal stations and by precipitation and/or scavenging elsewhere. Residence times with respect to export (total inventory divided by particulate flux) for phosphorus, cadmium, cobalt, and manganese in the upper 100 and 200 m were determined to be on the order of months to years. These GEOTRACES‐based synthesis efforts, combining a host of concentration and tracer data with unprecedented resolution, will help to close the oceanic budgets of trace metals.

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Section: Particulate CD Cyclingsupporting

confidence: 87%

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Black

Lam

Lee

et al. 2019

Global Biogeochemical Cycles

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“…PISCES reproduces the biogeochemical cycling of various macronutrients (phosphate PO 4 , nitrate NO 3 , ammonium NH 4 , and silicate Si), planktons (nanophytoplankton, diatoms, microzooplankton, and mesozooplankton), and one trace element (iron [Fe]). Recent developments allowed representing new trace elements such as manganese (Mn; Hulten et al, ) and cobalt (Co; Tagliabue et al, ) and gave new insights on the processes governing Fe distributions in the ocean (Tagliabue & Resing, ). Seven new tracers were implemented in PISCES in order to represent copper biogeochemical cycling: dissolved copper (DCu); scavenged copper, which represents copper adsorbed on the surface of particles (SCu, divided into small and large scavenged particles, SCup and SCug), this copper can be desorbed to the dissolved phase at depth; copper associated with biogenic particles (CuPart, divided into small and large copper particles, pCuPart and gCuPart) that can only be resupplied via bacterial activity; and copper in phytoplankton cells (Cu ϕ , with ϕ = N for nanophytoplankton or ϕ = D for diatoms).…”

Section: Methodsmentioning

confidence: 99%

“…The general equation for scavenged Cu is presented in equation :

\frac{δ S C u}{δ t} = S c a v_{Cu} - s i n k i n g,

with Scav Cu as copper scavenging and sinking as SCu sinking rate, increasing with depth following the same equations as C, Fe, and Co (Tagliabue et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…The biogeochemical parameter values are based on the PISCES general equations valid for macronutrients (Aumont et al, ), Fe (Tagliabue & Resing, ), and Co (Tagliabue et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…Cu uptake by phytoplankton is modeled following the Co model from Tagliabue et al () and is represented using an evolving Cu:P ratio in the planktonic cells (equation ).

U p_{Cu} = μ_{\max}^{ϕ} \times θ_{\max}^{ϕ} \times \frac{b C u}{b C u + k s C u_{ϕ}} \times \frac{1 - θ^{ϕ} false/ θ_{\max}^{ϕ}}{1.05 - θ^{ϕ} false/ θ_{\max}^{ϕ}} .

…”

Section: Methodsmentioning

confidence: 99%

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Insights Into the Major Processes Driving the Global Distribution of Copper in the Ocean From a Global Model

Richon

Tagliabue

2019

Global Biogeochemical Cycles

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Copper (Cu) is an unusual micronutrient as it can limit primary production but can also become toxic for growth and cellular functioning under high concentrations. Cu also displays an atypical linear profile, which will modulate its availability to marine microbes across the ocean. Multiple chemical forms of Cu coexist in seawater as dissolved species and understanding the main processes shaping the Cu biogeochemical cycling is hampered by key knowledge gaps. For instance, the drivers of its specific linear profile in seawater are unknown, and the bioavailable form of Cu for marine phytoplankton is debated. Here we developed a global 3‐D biogeochemical model of oceanic Cu within the NEMO/PISCES global model, which represents the global distribution of dissolved copper well. Using our model, we find that reversible scavenging of Cu by organic particles drives the dissolved Cu vertical profile and its distribution in the deep ocean. The low modeled inorganic copper (Cu') in the surface ocean means that Cu' cannot maintain phytoplankton cellular copper requirements within observed ranges. The global budget of oceanic Cu from our model suggests that its residence time may be shorter than previously estimated and provides a global perspective on Cu cycling and the main drivers of Cu biogeochemistry in different regions. Cu scavenging within particle microenvironments and uptake by denitrifying bacteria could be a significant component of Cu cycling in oxygen minimum zones.

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Efficient zinc/cobalt inter‐replacement in northeast Pacific diatoms and relationship to high surface dissolved Co : Zn ratios

Kellogg

McIlvin

Vedamati

et al. 2020

Limnology & Oceanography

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The importance of zinc (Zn) as a nutrient and its ability to be substituted for by cobalt (Co) have been characterized in model marine diatoms. However, the extent to which this substitution capability is distributed among diatom taxa is unknown. Zn/Co metabolic substitution was assayed in four diatom species as measured by the effect of free ion concentrations of Zn 2+ and Co 2+ on specific growth rate. Analysis of growth responses found substitution of these metals can occur within the northwest Atlantic isolate Thalassiosira pseudonana CCMP1335, the northeast Atlantic isolate Phaeodactylum tricornutum CCMP632, and within the northeast Pacific isolates Pseudo-nitzschia delicatissima UNC1205 and Thalassiosira sp. UNC1203. Metabolic substitution of Co in place of Zn in the Atlantic diatoms supports their growth in media lacking added Zn, but at the cost of reduced growth rates. In contrast, highly efficient Zn/Co substitution that supported growth even in media lacking added Zn was observed in the northeast Pacific diatoms. We also present new data from the northeast Pacific Line P transect that revealed dissolved Co and Zn ratios (dCo : dZn) as high as 3.52 : 1 at surface (0-100 m) depths. We posit that the enhanced ability of the NE Pacific diatoms to grow using Co is an adaptation to these high surface dCo : dZn ratios. Particulate metal data and single-cell metal quotas also suggest a high Zn demand in diatoms that may be partially compensated for by Co.

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The Role of External Inputs and Internal Cycling in Shaping the Global Ocean Cobalt Distribution: Insights From the First Cobalt Biogeochemical Model

Cited by 47 publications

References 91 publications

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Insights Into the Major Processes Driving the Global Distribution of Copper in the Ocean From a Global Model

Efficient zinc/cobalt inter‐replacement in northeast Pacific diatoms and relationship to high surface dissolved Co : Zn ratios

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The Role of External Inputs and Internal Cycling in Shaping the Global Ocean Cobalt Distribution: Insights From the First Cobalt Biogeochemical Model

Cited by 47 publications

References 91 publications

Insights From the238U‐234Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Insights From the238U‐234Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Insights Into the Major Processes Driving the Global Distribution of Copper in the Ocean From a Global Model

Efficient zinc/cobalt inter‐replacement in northeast Pacific diatoms and relationship to high surface dissolved Co : Zn ratios

Contact Info

Product

Resources

About

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean

Insights From the²³⁸U‐²³⁴Th Method Into the Coupling of Biological Export and the Cycling of Cadmium, Cobalt, and Manganese in the Southeast Pacific Ocean