The first set of experiments, Ice texture Exp., was conducted onboard RV Polarstern, and aimed at identifying the effects of different ice growth rates on ice crystal structure, i.e., ice texture. Seawater used for these experiments was collected during a winter cruise in the Weddell Sea onboard the RV Polarstern (ANT-XXIX/6, Lemke and Participants, 2014), using the ship water intake line. The ice was grown at −10, −15, and −20°C, for 24, 8, and 6.45 h respectively, and processed for ice texture analysis onboard the ship (Table 1).

A second set of experiments, EPS, POC, PON, and macro-nut. Exp., was run during the same voyage. Seawater was collected using the ship water intake line, a CTD or a peristaltic pump (E/S Portable Sampler, Masterflex) at different locations and different water depths (Table 1) to study the incorporation of EPS, POC, and particulate organic nitrogen (PON) and inorganic macro-nutrients (NO₂+NO₃ = NO_x, Si(OH)4-, PO43-, and NH4+) into sea ice. The first source solution was surface seawater (Surface SW, ship water intake line). The second source solution was deep seawater (Deep SW) collected with the CTD at 4,300 m depth. In the third source solution (Surface SW + XG), 5 mg L⁻¹ of xanthan gum (XG) from Xanthomonas campestris (Sigma-Aldrich) was added to the surface seawater sampled with a peristaltic pump (E/S Portable Sampler, Masterflex) at the ice-water interface. To achieve this, a stock solution of 1,000 mg L⁻¹ XG was made and sonicated for 60 min using a Bandelin Sonopuls sonicator. The stock solution was then diluted 10 times in Ultra High Purity (UHP) water (Millipore, Gradient A10) and sonicated for 30 min before being added to the surface seawater.

A third set of experiments, Iron Exp., aimed at assessing the role of organic matter in the incorporation of Fe into growing sea ice. Experiments were conducted under trace metal clean conditions at the University of Tasmania. Surface seawater was collected on the 9th of October 2015 from Trumpeter Bay, (Tasmania: 43°16 S, 147°39 E) using a shoreline, and stored in acid-clean low-density polyethylene (LDPE, Nalgene) carboys. The sampling depth was approximately 2.5 m. In the home laboratory, seawater was filtered through polycarbonate (PC) membranes (Sterlitech, pore size: 0.4 μm) at low vacuum (<0.13 bar) using an acid-clean PC filtration apparatus (Sartorius) under a class-100 laminar flow hood (AirClean 600 PCR workstation, Model 300 Controller, AirClean System).

Filtered seawater (FSW) was divided into separate bottles for separate sets of treatments. Triplicate bottles were then spiked with different types of Fe. Added concentrations were selected to reach detectable Fe signals during analyses, despite the small volume of sea ice formed and remaining seawater. The first source solution, “FSW + PFe,” was obtained by adding 30 μM of lithogenic PFe (PFe > 0.4 μm) to the FSW. Dust particles < 20 μm were used, collected in the Atacama desert, Chile (European Southern Observatory, Paranal), assuming a composition of 5% (w:w) of Fe, similar to the Earth's Crust (Taylor, 1964).

A second source solution, “FSW + DFe,” was obtained by adding 30 μM of DFe (DFe < 0.4 μm) into the FSW using a commercial solution of 1,000 ppm of FeCl₃ (Merck).

Two complementary sets of experiments were run after UV-treatment of the FSW. This UV exposure step ensured the destruction of any dissolved organic matter (DOM) present in the solution (Queroue et al., 2014). Filtered seawater was dispensed into acid-clean 0.5 L Teflon fluorinated ethylene propylene (FEP) bottles (Nalgene) and placed between ultraviolet lamps inside a black PVC chamber for 15 min. After UV exposure, PFe or DFe was added to the source solution following the steps adopted in treatments “FSW + PFe” and “FSW + DFe.” The latter treatments are referred to as “UV-FSW + PFe” and “UV-FSW + DFe.”

A final experiment was carried out using FSW to which 44 mL of melted bottom sea ice containing algae was added. The ice sample was collected at Davis station, Antarctica in November 2015 and maintained under optimum growth conditions in the IMAS culture room until the start of the experiment. This treatment, named “FSW + Algae,” aimed at studying the incorporation of biogenic PFe in sea ice. A list of the treatments is given in Table 1.

Melted ice and seawater samples were homogenized and filtered onto 25 mm diameter PC membranes (0.4 μm, Millipore) under low vacuum (<0.13 bar) to avoid cell lysis. Filters were stained with 500 μL of a solution of Alcian Blue (AB, GX8 Sigma, 0.02% AB in 0.06% acetic acid). Excess dye was removed by rinsing the membrane with 2 mL of UHP water (Millipore, Gradient A10). Membranes were then stored individually at −20°C in the dark until analysis. Concentrations were determined colorimetrically using the method of Passow and Alldredge (1995) and modified by van der Merwe et al. (2009). Concentrations were computed using the filter capture efficiency of 4% from van der Merwe et al. (2009).

All glassware used for POC and PON analysis were soaked in a 2% (v:v) HCl solution (analytical grade Merck EMSURE Germany), rinsed with UHP water, wrapped in aluminum foil and combusted at 450°C for 4 h. In between triplicates and treatments, glassware was rinsed with UHP water, soaked in a 2% (v:v) HCl solution (analytical grade, Merck EMSURE Germany) for 8 h and rinsed thoroughly with UHP water. Samples for POC and PON were filtered onto pre-combusted 25 mm quartz filters (Sartorius). A 20 mL subsample of the filtrate was collected and stored at −20°C in the dark until analysis for macro-nutrient concentrations (NO_x, Si(OH)4-, PO43-, and NH4+). POC and PON samples were stored at −20°C in the dark until analysis. After acidification of the filters [30 μL of 10 % (v:v) HCl, Ajax Finichem] to remove inorganic carbon, POC and PON concentrations were determined using a Thermo Finnigan EA 1112 Series Flash Elemental Analyzer (precision 1%) at Central Science Laboratory (CSL, University of Tasmania). Silicic acid was analyzed using a photometric analyzer (Aquakem 250) and PO43-, NO_x, and NH4+ were analyzed with a Lachat Flow injection analyzer following the methods of Grasshoff et al. (2009). Detection limits were 0.1 and 0.002 mg L⁻¹ for each method, respectively.

All sampling LDPE bottles, PC containers, PC filtration sets, petri-dishes and other equipment in contact with the samples were cleaned following GEOTRACES recommendations (Cutter et al., 2017). Polycarbonate membranes for PFe and PAl were soaked in 10% (v:v) ultrapure HCl for a week, thoroughly rinsed with UHP water (Barnstead International, NANOpure Diamond polisher) and stored in UHP water until use. Before and between treatments and triplicates, the cold-finger was thoroughly rinsed with UHP water. Between triplicates, equipment used for Fe filtrations was thoroughly rinsed with UHP water, soaked in a 10% (v:v) HCl solution for 16 h and rinsed 5 times with UHP water.

Immediately after removing the ice from the PC bottle, the remaining seawater was filtered onto 0.4 μm pore size 47 mm diameter PC membrane filters (Sterlitech) using an acid-clean PC filtration set (Sartorius) under gentle vacuum (<0.13 bar). The filter was collected for measurements of PFe and PAl (particles > 0.4 μm) concentrations, and placed in acid-clean polystyrene petri-dishes. 60 mL of the filtrate was collected in LDPE bottles (Nalgene) and acidified to pH 1.8 with ultrapure HCl (Seastar from Choice Analytics) for DFe analysis. Once fully melted, the same process was applied to the melted sea ice. Filters were stored individually in acid-clean petri-dishes, triple bagged and kept at −20°C in the dark until analysis. The LDPE bottles containing the dissolved fraction were triple bagged and kept at ambient temperature until analysis.

Filters for PFe and PAl determination were digested using a mixture of strong acids following the method described in Bowie et al. (2010). Dissolved Fe samples were diluted 10 times to reduce sea salt matrix interferences effects during analysis. Particulate metals and DFe concentrations were then measured at the Central Science Laboratory (University of Tasmania) using a Sector Field Inductively Coupled Plasma Mass Spectrometer (ICP-MS, Element 2), following methods described in Bowie et al. (2010).

Figure 3 shows the enrichment indices for EPS and macro-nutrients in sea ice grown from Surface SW, Deep SW and Surface SW + XG. The horizontal line marks the EI = 1 (i.e., conservative incorporation). Results show that Si(OH)4-, NO_x, and PO43- behave conservatively during sea-ice formation, whatever the source solution may be. Enrichment indices were close or equal to one for the macro-nutrients in Surface SW, Deep SW and Surface SW + XG (mean ± SD = 1.0 ± 0.09, n = 9), except NH4+ that was enriched in the ice in each treatment. The largest signal was observed for NH4+, which is clearly enriched in sea ice compared to seawater, especially in the deep samples (Figure 3). We observed moderate evidence of a difference in incorporation of NH4+ between treatments (ANOVA F = 5.28, P = 0.082). A Tukey-HSD multiple comparison procedure showed that only the Deep SW and Surface SW + XG treatments could be distinguished (P = 0.07). EPS enrichment was variable and showed no significant differences (ANOVA F = 2.03, P = 0.212) between treatments. The highest EI_EPS was observed in the Surface SW treatment and the lowest EI_EPS was observed in the Deep SW treatment (Figure 3). The Deep SW experiment had the highest EINH4+ and also the lowest EI_EPS.

All EI_POC and EI_PON were well above 1 indicating an enrichment of POC and PON in newly-formed ice (Figure 4). Mean EI_POC and EI_PON were 50.5 ± 35.7 (n = 9) and 8.9 ± 6.4 (n = 9), respectively. There is no evidence of treatment difference for EI_POC (ANOVA F = 1.99, P = 0.186), and strong evidence of treatment difference for EI_PON (ANOVA F = 11.23, P = 0.005; Tukey-HSD Surface SW + XG and Deep SW, P = 0.038; Tukey-HSD Surface SW + XG and Surface SW, P = 0.005).

Figure 5 shows the enrichment indices for DFe and PFe in sea ice grown from the five different source solutions. The horizontal line marks the EI = 1 (i.e., conservative incorporation). Results show that DFe and PFe do not behave conservatively during sea-ice formation in any of the source solutions. Dissolved Fe was slightly enriched in sea ice compared to the source seawater solution in each treatment (EI_DFe > 1, t-test confidence level 95%, P = 0.002) and relatively stable between treatments (mean EI_DFe = 2.2 ± 0.9, Figure 5) with no evidence that EI_DFe differed across treatment groups (ANOVA F = 1.85, P = 0.196).

We observed a strong evidence of difference in incorporation of PFe between treatments (ANOVA F = 5.17, P = 0.035). The UV-FSW + DFe and FSW + Algae treatments groups could be distinguished at the 0.05 level (Tukey-HSD, P = 0.02). Ice was enriched in PFe in the treatments where lithogenic or biogenic PFe was added: FSW + PFe (EI_PFe = 1.3 ± 1.41, n = 3) and FSW + Algae (EI_PFe = 4.7 ± 2.8, n = 3; Figure 5). When lithogenic PFe was added and UV treatment applied, less PFe was incorporated in sea ice (UV-FSW + PFe, EI_PFe = 0.5 ± 0.3, n = 3) than without UV-treatment. The treatment where biogenic PFe was added (FSW + Algae) showed the highest EI_PFe of all treatments (EI_PFe = 4.7 ± 2.8, n = 3).

Particulate organic matter (POC and PON) was more enriched in sea ice in treatments where PFe was added than in treatments where DFe was added (EI_POC: ANOVA, F = 23.14, P = 0.003; and EI_PON: ANOVA, F = 24.57, P = 0.000). Unlike other parameters, POC was the only compound showing a higher EI in UV-treated than in its non-UV treated equivalent. The enrichment index of PON was always lower than EI_POC (ANOVA, F = 4.48, P = 0.040; Figure 6).

Overall, the FSW + DFe and UV-FSW + DFe treatments had the lowest EIs and the lowest variability with EI_PON of 1.1 ± 0.7, n = 3 and 0.8 ± 0.5, n = 3, respectively.

The treatments with addition of lithogenic and biogenic PFe, and no UV treatment (FSW + PFe and FSW + Algae) were the only ones where enrichment in all compounds (DFe, PFe, POC, and PON) was observed relative to the source solution (Figures 5, 6). This was not the case for the treatments where DFe was added (FSW + DFe and UV-FSW + DFe), or when UV light was applied, where, depending on the compound, enrichment or depletion was observed.

Aluminum can be used as a tracer of lithogenic Fe inputs (Lannuzel et al., 2014a). The PFe/PAl molar ratio in the ice was elevated in all treatments compared to the Earth crustal ratio of 0.33 (Taylor, 1964). Two different patterns were observed: In the treatments with addition of PFe (FSW + PFe, UV-FSW + PFe and FSW + Algae), PFe/PAl was higher in the ice than in the remaining seawater (Figure 7A), however, this was not statistically significant (ANOVA F = 0.68, P = 0.423). In these treatments, the PFe/PAl ratios in the ice were up to 2 times higher than the crustal ratio (Figure 7A). In the treatment with DFe addition (FSW + DFe and UV-FSW + DFe) the PFe/PAl ratio in the ice was lower than in the remaining seawater (ANOVA F = 9.60, P = 0.011). In these experiments with addition of DFe, the PFe/PAl ratios were two to three orders of magnitudes higher than the crustal ratio (Figure 7B).

EPS from deep seawater were the least enriched in the ice, although it had the highest initial concentration (0.10 μg xeq L⁻¹). Also, the addition of XG, a reference standard for EPS in marine environments (Passow and Alldredge, 1995), did not show a preferential enrichment compared to the natural EPS in other treatments. Deep-sea bacteria have been found to produce EPS (Mancuso Nichols et al., 2005b), and it could be that deep-water EPS have different surface properties (e.g., number of anionic groups) or molecular weights than EPS produced in surface waters. Decho (1990) reported that physico-chemical characteristics of EPS are influenced by their tertiary structure, which is dependent on the frequency and type of functional groups presence on the EPS. This could also affect the incorporation efficiency, with stickier EPS being more enriched (Meiners and Michel, 2017). These divergences in surface properties of EPS could also play an important role in the incorporation of NH4+ in this experiment. The highest NH4+ enrichment was found when EI_EPS was the lowest (Figure 3). EPS have a negatively charged surface due to the high content of poly-anionic sugars. They are stabilized by the presence of cations (such as e.g., K⁺ and Ca²⁺) (Kloareg and Quatrano, 1988; Verdugo et al., 2004). Also, the sticky properties of EPS determine the interaction of EPS with other components of the marine environment (Passow, 2002). Some authors (e.g., Krembs et al., 2002a; Meiners and Michel, 2017) have suggested that the negatively charged EPS would complex with NH4+, and helped by their stickiness, lead to the enrichment of NH4+ and EPS in the ice (Fripiat et al., 2017). However, the lack of correlation between EPS and NH4+ in our study does not support this hypothesis, and further study is needed to decipher this process. Microbial regeneration of NH4+ has been previously observed in young sea ice (Riedel et al., 2007). However, due to the short duration of our experiment we believe microbial regeneration alone cannot fully explain the enrichment of NH4+ in the ice. In an ice tank study, Krembs et al. (2011) found that concentrations of EPS were higher in the ice when Melosira arctica, a diatom found in Arctic sea ice, was added to the source solution compared to ice grown from saline solution containing different concentrations of XG, even if the concentration of XG was higher than the concentration of EPS produced by the diatom. Similarly, using a cold-finger apparatus similar to ours, Ewert and Deming (2011) showed that only native EPS produced by a cold-adapted marine bacterium (commonly found in sea ice) was preferentially incorporated in sea ice. Our results indicating that EPS from surface seawater are enriched in sea ice when compared to deep seawater are consistent with these previous findings, suggesting that the quality of EPS is a key parameter for its entrapment into sea ice.

Higher EI_POC than EI_PON are in line with previous reports of high POC and PON concentrations in young Antarctic sea ice (Janssens et al., 2016). In our laboratory study, POC and PON were more enriched in experiments using Antarctic unfiltered seawater compared with experiments conducted with filtered source solutions from Tasmania (Iron Exp.). The presence of biogenic material (phytoplankton, bacteria and EPS) in the unfiltered Antarctic sample could explain this higher enrichment compared to the filtered Tasmanian seawater sample. Also, similar to EPS, the quality of POC may control the degree of enrichment in sea ice. Due to its location, the coastal Tasmanian sampling site is under influence of terrestrial inputs bringing large amounts of allochtonous material to the pool of organic matter. This is in contrast to the Antarctic sampling sites, where the organic matter in the water column is mainly autochtonous. Zhou et al. (2014) showed that riverine DOM was less enriched in sea ice compared to autochtonous DOM, due to different molecular compositions, different affinity with other compounds, and with sea ice. Similarly, Müller et al. (2013) showed that the degree of dissolved organic carbon (DOC) enrichment depends on the chemical characteristics of the DOM. Our results suggest that the POC of potential terrestrial origin is less enriched in sea ice than the autochtonous Antarctic POC, by an order of magnitude. The reason why the POC is preferentially incorporated in the ice compared to PON remains unclear at this stage and this needs further investigations. One idea is EPS might have a higher POC/PON ratio or the organic matter in the ice comprises a mixed composition of live and dead material, with a higher carbon content relative to nitrogen.

The EI_PFe in FSW + Algae was found to be up to 4 times higher than in any other treatment, suggesting a better incorporation of the biogenic PFe compared to the lithogenic PFe. The bottom ice sample added to the FSW + Algae treatment was dominated by pennate diatoms such a Nitzschia stellata, N. lecointei, Fragillariopsis spec., and Entomoneis kjellmanii (Andreas Seger and Fraser Kennedy, personal communication). The large size of algal cells compared to the dust sample, may have lead to the preferential enrichment of biogenic PFe relative to lithogenic PFe. The added dusts were sieved through 20 μm nylon mesh, while mentioned diatom species can be as large as 150 μm in cell size (Scott and Marchant, 2005), and can also form colonies and ribbon-chain like assemblages (Scott and Marchant, 2005; Aslam et al., 2012). Better incorporation of larger cells and impurities has been previously observed in natural young sea ice (Gradinger and Ikävalko, 1998; Riedel et al., 2007; Rózanska et al., 2008; Janssens et al., 2016).

Algal-bound EPS could also play a role in the incorporation of PFe into sea ice. Assemblages of diatoms are predominant in autotrophic-dominated sea-ice habitats and known to be associated to, and the main producers of, EPS (Krembs and Engel, 2001; Meiners et al., 2003, 2004; Mancuso Nichols et al., 2005a,b; Underwood et al., 2010, 2013). Particulate EPS have been shown to be likely of algal origin and quickly enriched into sea ice (Meiners et al., 2003; Riedel et al., 2007). EPS enrichment has been previously observed in cold-finger (Ewert and Deming, 2011) and ice tank experiments (Krembs et al., 2011). Negatively charged EPS (Decho, 1990; Mancuso Nichols et al., 2005a) are considered to be important in binding cationic metals like Fe³⁺ and Fe²⁺. In return, Fe provides some stability to the EPS network by acting as bridging ions (e.g., Brown and Lester, 1982; Decho, 1990).

Finally, EPS are two to four orders of magnitude stickier than other particles (Passow, 2002), therefore potentially further helping the adhesion of PFe to ice surfaces. One can therefore assume that EPS were an important component of the added melted bottom ice sample to the source solution in the FSW + Algae treatment, contributing to the preferential enrichment in biogenic PFe compared to lithogenic PFe. Krembs et al. (2011) showed that the presence of EPS in the ice changes the microstructure of the ice and alters it physical properties. Thus, it is also possible that these modified properties are beneficial for PFe incorporation (more adapted shape of the pores and an increased internal sea ice surface area) but this requires further investigation.

The DFe fraction was less affected by the addition of algae than the PFe fraction. EPS range in size from sub-microns to hundreds of microns in the marine environment (Passow and Alldredge, 1995). EPS produced by sea-ice algae are known to be in the colloidal and soluble form (Aslam et al., 2012). In this study, a size distinction of 0.4 μm was used to define the dissolved and particulate fractions. This definition is however operationally defined and organic matter actually consists of a size continuum spanning across the soluble, colloidal and particulate size fractions. The colloidal material is operationally in the dissolved fraction as it is defined as the fraction that can pass through a filter with pore size of 0.1 to 0.46 μm (Chin et al., 1998). van der Merwe et al. (2009) suggested that organically-bound DFe in the ice shows reduced loss to the water column when brine drainage occurs by being associated with particles or cells (Sunda, 2001). The retention of DFe by EPS could explain the lower EI_DFe in the UV-treated FSW + DFe experiment.

When subject to high UV exposure, DOM is degraded and ultimately transformed into carbon dioxide (CO₂) and water (H₂O). The UV- and non UV-treated experiments aimed at understanding the role of organic matter, including organic ligands such as EPS, in the incorporation of Fe into sea ice. It has been shown that photochemical reactions alter the concentration and reactivity of the organic ligands involved in the complexation/solubilisation of trace metals (Moffett, 1995). More specifically, photochemical reduction of organically bound Fe decreases ligand-binding strength, rendering the complexed Fe more labile and increasing its bioavailability (Barbeau et al., 2001).

In this study, Fe was added to seawater solutions after UV treatment. While results between UV and non-UV treatments were not statistically significant, different enrichment behaviors for Fe and organic matter were observed between UV-treated and non-UV treated source solutions. The lack of statistical significance is a result of the large variance of the data set compared to the limited size of the data set. Further studies are needed to elucidate the full impact of UV treatment on the incorporation of organic matter into sea ice.

Nevertheless, as expected, DFe (and PFe) enrichment decreased when UV treatment was applied to FSW + DFe. This experiment suggests that the presence and quality of organic matter influences the incorporation of DFe into growing sea ice. However, DFe enrichment increased when UV treatment was applied to FSW + PFe. In the former treatments, the DFe was not present in excess; as such precipitation of DFe into PFe was not observed (see section Conversion of Dissolved Fe to Particulate Form). It is suggested that, in the latter case, the UV treatment resulted in the release of dissolved organic ligands from the degradation of particulate organic matter. These “newly-formed” ligands were then able to complex DFe and carry DFe into sea ice leading to higher EI_DFe in UV-FSW + PFe than in FSW + PFe, where dissolved organic ligands were more sparse. The difference in enrichment efficiency of DFe in (UV-)FSW+ PFe and (UV-)FSW + DFe by a combined effect of “ligand saturation” and precipitation of DFe into PFe can be explained in this way (see section Conversion of Dissolved Fe to Particulate Form). The UV-broken bound effect might have been compensated by the production of new dissolved organic ligands available for DFe. However, not enough dissolved organic ligands were present in solution to keep the added 30 μM of DFe in solution in the FSW + DFe treatment. Free DFe remaining in seawater therefore precipitated into PFe (see section Conversion of Dissolved Fe to Particulate Form), leading to the high PFe/PAl ratios observed.

As observed in the case of DFe incorporation in the (UV-)FSW + DFe treatments, PFe enrichment decreased when UV treatment was applied to FSW + PFe and FSW + DFe. This indicates the role of organic matter in the incorporation of PFe in growing sea ice. Unlike EI_PFe and EI_DFe, EI_POC increased when UV treatment was applied to FSW + PFe. It has been proposed that UV-B radiation breaks down not only DOC but also POC (UNEP, 1999), although the effect of UV on particulate organic matter is not clearly defined. Results here show that UV could impact on the quality of POC (including EPS) leading to different incorporation behaviors. It is likely that the POC becomes smaller when UV is applied and is then more easily incorporated into the ice. This argument however contradicts what has been previously observed in the field, where large particles are preferentially incorporated in sea ice (Gradinger and Ikävalko, 1998; Riedel et al., 2007; Lannuzel et al., 2014b; Janssens et al., 2016).

One explanation is that UV-radiation changes the physico-chemical properties of organic matter in a way that the PFe-organic matter binding capacity would be reduced, but the enrichment of POC would be favored. Organic-free PFe would therefore be hardly incorporated, while the UV-induced modifications in the POC facilitate its incorporation. It has been shown that the binding potential of EPS is greatly influenced by their physico-chemical properties (Krembs and Deming, 2008; Verdugo, 2012), which are likely to be altered by UV irradiation. Therefore, more than the size, the important factor for enrichment of particles would be their physico-chemical properties and the tertiary structure/molecular composition/shape of the particles. Zhou et al. (2014) suggested that organic matter is initially incorporated as particulate organic matter and then converted into DOM once in the ice. This process may be observed in the FSW + Algae treatment, with the transformation of POC into DOC by heterotrophic organisms, leading to lower EI_POC than in (UV-)FSW + PFe. However, we note that 8 h of incubation time may not be sufficient for significant transformation. Zhou et al. (2014) also showed that different quality of DOC impacts the incorporation efficiency. It is suggested that this mechanism is also applicable to particulate constituents as discussed in section Lithogenic vs. Biogenic Iron: Role of EPS Produced by Ice Algae and Bacteria.

The PFe/PAl ratios measured in the samples can give an indication on the level of conversion of DFe into PFe. The addition of DFe into seawater led to very high PFe/PAl ratios in the FSW + DFe and UV-FSW + DFe experiments (Figure 7B). A significant amount of DFe (30 μM) was added to these 2 solutions, without addition of organic ligands (e.g., EDTA) to balance the addition of DFe and keep it in solution. Organic ligands can be produced in situ by sea-ice algae and bacteria (Lannuzel et al., 2015) or supplied externally from e.g., sediment resuspension (Croot and Johansson, 2000; Buck et al., 2007). EDTA is synthetically produced and is therefore not an adequate model ligand of the natural environment.

The conversion observed here of the non-organically bound excess of DFe into the PFe pool (Lannuzel et al., 2014a, 2015), leads to the high PFe/PAl ratios observed. This process was even more expressed in the UV-FSW + DFe treatment, where the UV exposure likely broke the bounds of the Fe-ligand complexes already present in the source solution before addition of DFe. The newly formed PFe and remaining DFe could be then less prone to incorporation into sea ice, as observed by lower EI_PFe and EI_DFe. Two explanations are possible: (1) As previously mentioned in the preceding section, biogenic PFe (low in these experiments) is preferentially enriched in the newly-formed ice compared to lithogenic PFe. A decoupling between biogenic and lithogenic PFe incorporation could be observed. EPS have been proposed to be acting as a “plug,” retaining salinity in the ice (Krembs et al., 2011). If the biogenic PFe is incorporated first, helped by the association to, and then retained in the ice by EPS, the incorporation of lithogenic PFe might not be as efficient and could reach a concentration threshold in the ice. The association of Fe with EPS, as well as the space available in the brine channel system would therefore determine the incorporation, retention, and threshold of PFe in the ice.

(2) Organic ligands may play a key role in transferring DFe from seawater to sea ice. Organically-bound Fe would take advantage of the properties of the particles it is attached to, to get trapped in the ice as discussed previously (section Effect of UV Treatment on Fe Incorporation Efficiency: Importance of Organic Ligands).

It is difficult to distinguish the contribution of each process in these experiments and it is likely a combination of both. We note that Fe concentrations in these experiments were above the range of concentrations encountered in the Southern Ocean, although they are in the range of concentration found in Antarctic fast ice (Grotti et al., 2001; van der Merwe et al., 2011a,b; Noble et al., 2013). All conclusions in this study are derived from a high concentration scenario in regards to added DFe and PFe, but nonetheless, our results provide key information on the general chemistry of the involved processes.