Organic Matter Controls of Iron Incorporation in Growing Sea Ice

Janssens, Julie; Meiners, Klaus M.; Townsend, Ashley T.; Lannuzel, Delphine

doi:10.3389/feart.2018.00022

Cited by 9 publications

(8 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Imposing a constant DFe concentration in sea ice in the CST formulation assumes an instant saturation in sea ice. The continuous enrichment of DFe in young sea ice in the study of Janssens et al (2016) suggests that, aside from rapid processes such as ice nucleation or scavenging by frazil crystals, other processes also important for the incorporation of DFe into sea ice such as the role played by extracellular polymeric substances and particulate organic carbon (Janssens et al, 2018) are not accounted for by this very simplified approach. In addition, the reported variations in DFe concentrations in sea ice (de Jong et al, 2013(de Jong et al, , 2015Lannuzel et al, 2007Lannuzel et al, , 2008Lannuzel et al, , 2011Lannuzel et al, , 2016van der Merwe et al, 2011) strongly suggest that there is no saturation of the Fe storage capacity of sea ice as long as enough organic ligands are present to keep Fe in the dissolved phase.…”

Section: Is There a Best Formulation For Iron Incorporation Into Sea mentioning

confidence: 99%

“…Iron-rich waters favor Fe incorporation, in particular near sediment sources, as suggested by summer land-fast sea ice cores from the McMurdo area (de Jong et al, 2013). Dissolved Fe within brine samples is generally much lower than retrieved from melted ice core sections, which suggests the adsorption of DFe onto something within sea ice (Lannuzel et al, 2016), possibly aided by the presence of Fe-binding organic ligands such as exopolysaccharides (Janssens et al, 2018;Lannuzel et al, 2007Lannuzel et al, , 2015. This supposition is reinforced by the strong association of DFe with organic matter in sea ice, which suggests a prominent role of biology-for instance biological assimilation into growing algae or recycling by organic matter.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Iron Incorporation From Seawater Into Antarctic Sea Ice: A Model Study

Person

Vancoppenolle

Aumont

2020

Global Biogeochemical Cycles

View full text Add to dashboard Cite

Sea ice acts as an iron (Fe) reservoir in the Southern Ocean (SO) where primary productivity is largely Fe limited. The mechanisms leading to Fe enrichment in sea ice result from the combination of poorly understood and largely unexplored physical and biological processes. We analyze the biogeochemical impacts of three plausible idealized formulations of dissolved Fe (DFe) incorporation into sea ice corresponding to (i) constant Fe concentration in sea ice, (ii) constant ocean-ice Fe flux, and (iii) ocean-ice Fe flux linearly varying with seawater Fe concentration in a global ocean-sea-ice-biogeochemical model, focusing on the SO. The three formulations simulate different geographical distributions of DFe concentrations in sea ice. Iron in sea ice remains largely uncertain due to the limited number of spatial and seasonal observations, poorly constrained Fe sources and sinks, and significant uncertainties in simulated sea ice and hydrography. Despite these differences, the fertilization effect by sea ice on phytoplankton photosynthesis is qualitatively similar regardless of the formulation considered. Iron incorporation during sea-ice formation, transport, and melt release, common to all formulations, dominates over differences in sea-ice Fe concentrations. Formulating the Fe incorporation rate as proportional to seawater Fe concentrations gives the closest agreement to field observations. With this formulation, sediments work in synergy with Fe transport to fertilize the waters north of the continental shelf. Southern Ocean primary production and export production increase by 5-10% and 9-19%, respectively, when Fe incorporation into sea ice is considered, suggesting a moderate effect of Fe-bearing sea ice on marine productivity. A large part of the SO is under the influence of the cryosphere, which involves several forms of ice: sea ice (pack ice and landfast ice), icebergs, and melting ice shelves. These cryospheric elements reduce light availability at the ocean surface. However, they are also iron laden, which is thought to stimulate productivity and carbon export (

show abstract

Section: Is There a Best Formulation For Iron Incorporation Into Sea mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Iron Incorporation From Seawater Into Antarctic Sea Ice: A Model Study

Person

Vancoppenolle

Aumont

2020

Global Biogeochemical Cycles

View full text Add to dashboard Cite

show abstract

“…Finally, all metals analyzed here were enriched in sea ice relative to seawater when normalized to salinity (Table 4). We suggest that organic ligands, most likely EPS, are responsible for this enrichment in sea ice, as they can bind a wide range of metal cations due to their negatively charged surfaces (van der Merwe et al, 2009;Janssens et al, 2018). The high uronic acid content of EPS (Decho and Gutierrez, 2017) provides EPS with the ability to chemically complex and adsorb metals, leading us to suggest EPS as a prime pathway for organic matter and metal incorporation into newly forming sea ice.…”

Section: Drivers Of Dissolved Metal Distributionsmentioning

confidence: 85%

Spatial and seasonal distribution of dissolved and particulate bioactive metals in Antarctic sea ice

Duprat

Townsend

Merwe

et al. 2021

Elementa: Science of the Anthropocene

Self Cite

View full text Add to dashboard Cite

Iron (Fe) has been shown to limit growth of marine phytoplankton in the Southern Ocean, regulating phytoplankton productivity and species composition, yet does not seem to limit primary productivity in Antarctic sea ice. Little is known, however, about the potential impact of other metals in controlling sea-ice algae growth. Here, we report on the distribution of dissolved and particulate cadmium (Cd), cobalt (Co), copper (Cu), manganese (Mn), nickel (Ni), and zinc (Zn) concentrations in sea-ice cores collected during 3 Antarctic expeditions off East Antarctica spanning the winter, spring, and summer seasons. Bulk sea ice was generally enriched in particulate metals but dissolved concentrations were similar to the underlying seawater. These results point toward an environment controlled by a subtle balance between thermodynamic and biological processes, where metal availability does not appear to limit sea-ice algal growth. Yet the high concentrations of dissolved Cu and Zn found in our sea-ice samples raise concern about their potential toxicity if unchelated by organic ligands. Finally, the particulate metal-to-phosphorus (P) ratios of Cu, Mn, Ni, and Zn calculated from our pack ice samples are higher than values previously reported for pelagic marine particles. However, these values were all consistently lower than the sea-ice Fe:P ratios calculated from the available literature, indicating a large accumulation of Fe relative to other metals in sea ice. We report for the first time a P-normalized sea-ice particulate metal abundance ranking of Fe >> Zn ≈ Ni ≈ Cu ≈ Mn > Co ≈ Cd. We encourage future sea-ice work to assess cellular metal quotas through existing and new approaches. Such work, together with a better understanding of the nature of ligand complexation to different metals in the sea-ice environment, would improve the evaluation of metal bioavailability, limitation, and potential toxicity to sea-ice algae.

show abstract

“…The negatively charged surface of EPS (Decho, 1990;Nichols et al, 2005a) helps bind cationic metals like Fe 3+ and Fe 2+ . This together with the fact that EPS in marine systems, can be several orders of magnitude more adhesive than other particles (Passow, 2002), facilitates the attachment and adhesion of PFe in sea ice (Janssens et al, 2018;Lannuzel et al, 2016). EPS thus serves as an organic ligand that controls DFe enrichment in sea ice (Lannuzel et al, 2015).…”

Section: Iron Biogeochemical Cyclementioning

confidence: 99%

“…They play an important role in the formation of biofilms on glacier surfaces, promoting efficient transfer J o u r n a l P r e -p r o o f and cycling of nutrients (Smith et al, 2016). They also contribute to mineral precipitation (Norman et al, 2015;Or et al, 2007), production of organic matter (Nichols et al, 2005a), and biogeochemical cycling of elements Janssens et al, 2018;van der Merwe et al, 2009) in the environment. EPS is not only produced by cyanobacteria and heterotrophs, but also consumed and re-assimilated by them (Stuart et al, 2016), thus fuelling the microbial web (Almela et al, 2019).…”

Section: Introductionmentioning

confidence: 99%