Fe(II) stability in coastal seawater during experiments in Patagonia, Svalbard, and Gran Canaria

Hopwood, Mark J.; Santana-González, Carolina; Gallego-Urrea, Julián Alberto; Sánchez, Nicolás; Achterberg, Eric P.; Ardelan, Murat Van; Gledhill, Martha; González‐Dávila, Melchor; Hoffmann, Linn; Leiknes, Øystein; Santana‐Casiano, J. Magdalena; Tsagaraki, Tatiana M.; Turner, David R.

doi:10.5194/bg-17-1327-2020

Cited by 21 publications

(9 citation statements)

References 88 publications

(103 reference statements)

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“…142 Shaked et al (2020) 129 emphasized that the enhancement of Fe bioavailability due to photoreduction of Fe(III) may be especially important in the Arctic Ocean, because low temperatures retard the reoxidation of Fe(II) to Fe(III). Hopwood et al (2020) 147 measured Fe(II) in surface coastal waters of Patagonia and Svalbard, where a dynamic redox cycle operates, maintaining considerable concentrations of Fe(II) in solution. The results by Hopwood et al 147 suggested that the observed reoxidation delay of Fe(II) to Fe(III) was possibly due to the autochthonous production of marine Fe(II)-binding ligands.…”

Section: The Total Dissolved Fe(iii) Concentration [Fe T ] Is Given Bymentioning

confidence: 99%

Northern High-Latitude Organic Soils As a Vital Source of River-Borne Dissolved Iron to the Ocean

Krachler

2021

Environ. Sci. Technol.

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Organic soils in the Arctic−boreal region produce small aquatic humic ligands (SAHLs), a category of naturally occurring complexing agents for iron. Every year, large amounts of SAHLsloaded with iron mobilized in river basinsreach the oceans via river runoff. Recent studies have shown that a fraction of SAHLs belong to the group of strong iron-binding ligands in the ocean. That means, their Fe(III) complexes withstand dissociation even under the conditions of extremely high dilution in the open ocean. Fe(III)-loaded SAHLs are prone to UV-photoinduced ligand-to-metal charge-transfer which leads to disintegration of the complex and, as a consequence, to enhanced concentrations of bioavailable dissolved Fe(II) in sunlit upper water layers. On the other hand, in water depths below the penetration depth of UV, the Fe(III)-loaded SAHLs are fairly resistant to degradation which makes them ideally suited as long-lived molecular transport vehicles for river-derived iron in ocean currents. At locations where SAHLs are present in excess, they can bind to iron originating from various sources. For example, SAHLs were proposed to contribute substantially to the stabilization of hydrothermal iron in deep North Atlantic waters. Recent discoveries have shown that SAHLs, supplied by the Arctic Great Rivers, greatly improve dissolved iron concentrations in the Arctic Ocean and the North Atlantic Ocean. In these regions, SAHLs play a critical role in relieving iron limitation of phytoplankton, thereby supporting the oceanic sink for anthropogenic CO 2 . The present Critical Review describes the most recent findings and highlights future research directions.

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Section: The Total Dissolved Fe(iii) Concentration [Fe T ] Is Given Bymentioning

confidence: 99%

Northern High-Latitude Organic Soils As a Vital Source of River-Borne Dissolved Iron to the Ocean

Krachler

2021

Environ. Sci. Technol.

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“…DFe distribution in surface water at our study area was significantly affected by atmospheric input indicated by the same patterns of DFe with DAl distributions. The distribution of Fe in seawater is controlled by rate of Fe stabilisation (formation of organic binding ligands) and Fe removal processes (Hopwood et al, 2020;Shaked et al, 2020). Marine organism (i.e.…”

Section: Resultsmentioning

confidence: 99%

Atmospheric Iron and Aluminium Deposition and Sea-Surface Dissolved Iron and Aluminium Concentrations in the South China Sea off Malaysia Borneo (Sarawak Waters)

Idrus¹,

Mohamed

Rahim

et al. 2021

BJRST

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South China Sea (SCS) is an oligotrophic sea which usually receives low nutrients supply. However, massive atmospheric dust input was occurred during the haze event in Southeast Asia for almost every year. The input of dissolved iron (DFe) and dissolved aluminium (DAl) from dust and nearby land into SCS off Sarawak Borneo region during the worst haze event in 2015 of the Southeast Asia were investigated. The estimation dust deposition during this study was 0.162 mg/m2/yr. The atmospheric fluxes of total Fe and total Al at the offshore Sarawak waters were 0.611 µmol/m2/yr and 2.03 µmol/m2/yr, respectively, where the readily available dissolved Fe and Al from the dust were 0.11 µmol/m2/yr (DFe) and 0.31 µmol/m2/yr (DAl). Fe has higher solubility (17.78%) than Al (15.21%). The lateral fluxes (e.g. from the nearby land) were 37.08 nmol/m2/yr (DFe) and 125 nmol/m2/yr (DAl), with strong Fe organic ligand class L1 (log K:22.43 – 24.33). High concentrations of DFe and DAl at the surface water of the offshore region, coincided with high concentration of macronutrients due to the prevailing south-westerly winds originated from the west Kalimantan. Low residence times, ~0.92 (DFe) and ~1.31 (DAl) years, corresponded well with DAlexcess in surface seawater due to biological utilization of DFe. Future works emphasize on natural organic Fe(III) ligands and phytoplankton study are needed for better understanding on biogeochemistry of Fe and Al at SCS off Malaysia Borneo.

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“…Reported Fe concentrations determined by a diffusive gel technique in Reloncaví Fjord in October 2006 were found to be relatively high; 46-530 nM (Ahumada et al, 2011). Similarly, reported dFe concentrations in the adjacent Comau Fjord at higher salinity are generally in the nanomolar range and remain >2 nM even under post-bloom conditions which suggests dFe is not a limiting factor for phytoplankton growth (Hopwood et al, 2020;Sanchez et al, 2019).…”

Section: Local Drivers Of 2015 Bloom Dynamics In Reloncaví Fjordmentioning

confidence: 93%

A mosaic of phytoplankton responses across Patagonia, the SE Pacific and SW Atlantic Ocean to ash deposition and trace metal release from the Calbuco 2015 volcanic eruption

Vergara-Jara¹,

Hopwood²,

Browning³

et al. 2020

Preprint

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Abstract. Following the April 2015 eruption of the Calbuco volcano, an extensive ash plume spread across northern Patagonia and into the SE Pacific and SW Atlantic Ocean. Here we report the results of field surveys conducted in the marine region receiving the highest ash load following the eruption (Reloncaví Fjord). The fortuitous location of a long-term monitoring station in Reloncaví Fjord provided data to evaluate inshore phytoplankton bloom dynamics and carbonate chemistry during April–May 2015. Satellite derived chlorophyll-a measurements over the ocean regions affected by the ash plume in May 2015 were obtained to determine the spatial-temporal gradient in offshore phytoplankton response to ash. Additionally, leaching experiments were performed to quantify the release of total alkalinity, trace elements (Fe, Mn, Pb, Co, Cu, Ni and Cd) and major ions (Fl, Cl, SO4, NO3, Li, Na, NH4, K, Mg, Ca) from ash into solution. Within Reloncaví Fjord, integrated peak diatom abundances during the May 2015 austral bloom were higher than usual (up to 1.4 × 1011 cells m−2, integrated to 15 m depth), with the bloom intensity perhaps moderated due to high ash loadings in the two weeks following the eruption. In the offshore SE Pacific, a short duration phytoplankton bloom corresponded closely in space and time to the maximum observed ash plume, potentially in response to Fe-fertilization of a region where phytoplankton growth is typically Fe-limited at this time of year. Conversely, no clear fertilization was found in the area subject to an ash plume over the SW Atlantic where the availability of fixed nitrogen is thought to limit phytoplankton growth which was consistent with no significant release of fixed nitrogen from ash. In addition to release of nanomolar concentrations of dissolved Fe from ash suspended in seawater, it was observed that low loadings (

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Fe(II) stability in coastal seawater during experiments in Patagonia, Svalbard, and Gran Canaria

Cited by 21 publications

References 88 publications

Northern High-Latitude Organic Soils As a Vital Source of River-Borne Dissolved Iron to the Ocean

Northern High-Latitude Organic Soils As a Vital Source of River-Borne Dissolved Iron to the Ocean

Atmospheric Iron and Aluminium Deposition and Sea-Surface Dissolved Iron and Aluminium Concentrations in the South China Sea off Malaysia Borneo (Sarawak Waters)

A mosaic of phytoplankton responses across Patagonia, the SE Pacific and SW Atlantic Ocean to ash deposition and trace metal release from the Calbuco 2015 volcanic eruption

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