Replacement Times of a Spectrum of Elements in the North Atlantic Based on Thorium Supply

Hayes, Christopher T.; Anderson, Robert F.; Cheng, Hai; Conway, Tim M.; Edwards, R. Lawrence; Fleisher, Martin Q.; Ho, Peng; Huang, Kuo-Fang; John, Seth G.; Landing, William M.; Little, Susan H.; Lü, Yanbin; Morton, Peter L.; Moran, S. Bradley; Robinson, Laura F.; Shelley, Rachel; Shiller, Alan M.; Zheng, Xin-Yuan

doi:10.1029/2017gb005839

Cited by 41 publications

(54 citation statements)

References 96 publications

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“…Prior work suggests that over modest basin‐wide spatial‐temporal scales, dissolved Ga is relatively unreactive (Hayes et al, 2018; Shiller, 1998; Shiller & Bairamadgi, 2006). Where Ga shows clear nonconservative behavior, there is an influence of particles by atmospheric input (Orians & Bruland, 1988; Shiller, 1988) or by scavenging in particle‐rich river plumes (McAlister & Orians, 2012).…”

Section: Resultsmentioning

confidence: 99%

Gallium: A New Tracer of Pacific Water in the Arctic Ocean

et al. 2020

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Determining the proportions of Atlantic and Pacific Ocean seawater entering the Arctic Ocean is important both for understanding the mass balance of this basin as well as its contribution to formation of North Atlantic deep water. To quantify the distribution and amount of Pacific and Atlantic origin seawater in the western Arctic Ocean, we used dissolved Ga in a four‐component linear endmember mixing model. Previously, nutrients, combined in their Redfield ratios, have been used to separate Pacific‐ and Atlantic‐derived waters. These nutrient tracers are not conservative in practice, and there is a need to find quantities that are conserved. Dissolved Ga concentrations show measurable contrast between Atlantic and Pacific source waters, shelf‐influenced waters show little impact of shelf processes on the dissolved Ga distribution, and dissolved Ga in the Arctic basins is conserved along isopycnal surfaces. Thus, we explored the potential of Ga as a new parameter in Arctic source water deconvolution. The Ga‐informed deconvolution was compared to that generated with the NO3:PO4 relationship. While distributions of the water masses were qualitatively similar, the Ga‐based deconvolution predicted higher amounts of Pacific water at depths between 150 and 300 m. The Ga‐based decomposition yields a smoother transition between the halocline and Atlantic layers, while nutrient‐based solutions have sharper transitions. A 1‐D advection‐diffusion model was used to constrain estimates of vertical diffusivity (Kz). The Ga‐based Kz estimates agreed better with those from salinity and temperature than the nutrient method. The Ga‐based approach implies greater vertical mixing between the Pacific and Atlantic waters.

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Section: Resultsmentioning

confidence: 99%

Gallium: A New Tracer of Pacific Water in the Arctic Ocean

et al. 2020

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“…That is, much of the Loihi Fe may persist to be upwelled. However, shorter estimates of deep water Fe replacement timescales of <20 years have also been recently proposed based on comparison to Th fluxes (Hayes et al, 2018(Hayes et al, , 2015 which would suggest that perhaps none of the Loihi Fe would reach surface phytoplankton. The uncertainty in Fe scavenging rates means that the biogeochemical impact of Loihi Fe fluxes can only be assessed with a biogeochemical model containing dynamic Fe transformations.…”

Section: Estimating the Hydrothermal Iron Fluxmentioning

confidence: 99%

An intermediate-depth source of hydrothermal 3He and dissolved iron in the North Pacific

Jenkins

Hatta

Fitzsimmons

et al. 2020

Earth and Planetary Science Letters

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We observed large water column anomalies in helium isotopes and trace metal concentrations above the Loihi Seamount. The 3 He/ 4 He of the added helium was 27.3 times the atmospheric ratio, clearly marking its origin to a primitive mantle plume. The dissolved iron to 3 He ratio (dFe: 3 He) exported to surrounding waters was 9.3 ± 0.3 × 10 6. We observed the Loihi 3 He and dFe "signal" at a depth of 1100 m at several stations within ∼100-1000 km of Loihi, which exhibited a distal dFe: 3 He ratio of ∼4 × 10 6 , about half the proximal ratio. These ratios were remarkably similar to those observed over and near the Southern East Pacific Rise (SEPR) despite greatly contrasting geochemical and volcanictectonic origins. In contrast, the proximal and distal dMn: 3 He ratios were both ∼ 1 × 10 6 , less than half of that observed at the SEPR. Dissolved methane was minimally enriched in waters above Loihi Seamount and was distally absent. Using an idealized regional-scale model we replicated the historically observed regional 3 He distribution, requiring a hydrothermal 3 He source from Loihi of 10.4 ± 4.2 mol a −1 , ∼2% of the global abyssal hydrothermal 3 He flux. From this we compute a corresponding dFe flux of ∼40 Mmol a −1. Global circulation model simulations suggest that the Loihi-influenced waters eventually upwell along the west coast of North America, also extending into the shallow northwest Pacific, making it a possibly important determinant of marine primary production in the subpolar North Pacific.

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“…It is estimated that > 99% of bioavailable Fe (i.e., Fe that can be taken up by the biota) is chelated by organic ligands (Rue and Bruland, 1995;Gledhill and Buck, 2012). As the residence time of ligand-complexed Fe is long (months to years, Hayes et al, 2018), oceans can maintain levels of bioavailable Fe well above the concentration limits of aqueous inorganic forms.…”

Section: Introductionmentioning

confidence: 99%

Perspective on identifying and characterizing the processes controlling iron speciation and residence time at the atmosphere-ocean interface

et al. 2019

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It is well recognized that the atmospheric deposition of iron (Fe) affects ocean productivity, atmospheric CO 2 uptake, ecosystem diversity, and overall climate. Despite significant advances in measurement techniques and modeling efforts, discrepancies persist between observations and models that hinder accurate predictions of processes and their global effects. Here, we provide an assessment report on where the current state of knowledge is and where future research emphasis would have the highest impact in furthering the field of Fe atmosphere-ocean biogeochemical cycle. These results were determined through consensus reached by diverse researchers from the oceanographic and atmospheric science communities with backgrounds in laboratory and in situ measurements, modeling, and remote sensing. We discuss i) novel measurement methodologies and instrumentation that allow detection and speciation of different forms and oxidation states of Fe in deliquesced mineral aerosol, cloud/rainwater, and seawater; ii) oceanic models that treat Fe cycling with several external sources and sinks, dissolved, colloidal, particulate, inorganic, and organic ligand-complexed forms of Fe, as well as Fe in detritus and phytoplankton; and iii) atmospheric models that consider natural and anthropogenic sources of Fe, mobilization of Fe in mineral aerosols due to the dissolution of Fe-oxides and Fe-substituted aluminosilicates through proton-promoted, organic ligand-promoted, and photo-reductive mechanisms. In addition, the study identifies existing challenges and disconnects (both fundamental and methodological) such as i) inconsistencies in Fe nomenclature and the definition of bioavailable Fe between oceanic and atmospheric disciplines, and ii) the lack of characterization of the processes controlling Fe speciation and residence time at the atmosphere-ocean interface. Such challenges are undoubtedly caused by extremely low concentrations, short lifetime, and the myriad of physical, (photo)chemical, and biological processes affecting global biogeochemical cycling of Fe. However, we also argue that the historical division (separate treatment of Fe biogeochemistry in oceanic and atmospheric disciplines) and the classical funding structures (that often create obstacles for transdisciplinary collaboration) are also hampering the advancement of knowledge in the field. Finally, the study

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Replacement Times of a Spectrum of Elements in the North Atlantic Based on Thorium Supply

Cited by 41 publications

References 96 publications

Gallium: A New Tracer of Pacific Water in the Arctic Ocean

Gallium: A New Tracer of Pacific Water in the Arctic Ocean

An intermediate-depth source of hydrothermal 3He and dissolved iron in the North Pacific

Perspective on identifying and characterizing the processes controlling iron speciation and residence time at the atmosphere-ocean interface

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