3.2.1 Microscope observation and Raman analyses

We chose five ice layers, dated 1955, 1981, 2006, 2012, and 2014 in which to examine the inclusions using microscope observations and Raman analyses (Table S1). In these layers, we first examine the shape and size of 513 inclusions. Of the 513, the most common shapes are particle-like (n = 253) and rod-like (n = 230), with the remaining 30 classified as columnar-like.

Concerning this classification, we first check if the inclusion is angular, and if so, it is classified as columnar. If not, then we check if the noncolumnar inclusion has an aspect ratio (major-to-minor axes) exceeding 2:1, and if so, the inclusion is classified as rod-like. What remained were particle-like, an example of which is shown in Figure 3a. The particle-like inclusions occurred both in ice grains and on grain boundaries. The rod-like inclusions were found in grain boundaries and triple junctions (Fig. 3b) and had diameters of about 10–100 μm. This type generally had the longest lengths of all inclusions. Almost all rod-like inclusions were detected in thick ice layers such as those from 2012 and 2006 (e.g., Fig. 1b). The columnar-like inclusions were found in ice grains (Fig. 3c). Some of the particle- and columnar-like inclusions are greater than 30 μm in diameter.

Fig. 3.

Microscope images and Raman spectroscopy analyses of the three types of inclusions. (a) Particle-like inclusion in an ice grain from the 2014 ice layer, with peaks at 990 and 1008 cm⁻¹. At right is the distribution of chemical compositions of 85 particle-like inclusions from Raman analyses from all ice layers. Colors, defined at bottom, are based on peaks at 982, 984, 990, 1008 cm⁻¹. ‘Others’ means peaks found at other wavenumbers. (b) Rod-like inclusion in a grain boundary from the 2006 ice layer, with a peak of 984 cm⁻¹. Right side is the same as that in (a) except for 97 rod-like inclusions. (c) Columnar-like inclusion in a grain interior from the 2006 ice layer, with a peak of 1008 cm⁻¹. Right side is the same as that in (a) except for 30 columnar-like inclusions.

The chemical forms of the inclusions are measured by Raman spectroscopy. In the spectra, we look for peaks at 982, 984, 990, and 1008 cm⁻¹. The 982 and 984 cm⁻¹ peaks have a broad half-width, suggesting liquid inclusions. On the other hand, the 990 and 1008 cm⁻¹ peaks are sharp, suggesting solid inclusions. Following Ohno and others (Reference Ohno, Igarashi and Hondoh2005), we assume the 990 cm⁻¹ peak is Na₂SO₄⋅10H₂O, and the 1008 cm⁻¹ peak is CaSO₄⋅2H₂O. The broad peaks at 984 cm⁻¹ indicate SO₄²⁻ in a liquid phase (Sakurai and others, Reference Sakurai, Ohno, Horikawa, Motoyama and Uchida2017). However, we found no prior reference for the broad 982 cm⁻¹ peak, so we ran a few tests that identified the peak as SO₄²⁻ and NH₄⁺ in a liquid phase (Supplementary information).

Among our 525 measurements, 221 showed Raman peaks, whereas 304 measurements did not (Table S4). Of the 221 with peaks, 96% (n = 213) show at least one chemical compound at liquid (NH₄)₂SO₄, liquid H₂SO₄, solid Na₂SO₄⋅10H₂O, and solid CaSO₄⋅2H₂O. The breakdown of the 213 peaks is such that 31% have the liquid (NH₄)₂SO₄, 31% have the liquid H₂SO₄, 10% have the solid Na₂SO₄⋅10H₂O, and 28% have the solid CaSO₄⋅2H₂O (Table S4).

The specific peaks depend on the inclusion's shape-type as shown by the pie charts on right side of Figure 3. Among the particle-like type, individual inclusions had one or two compounds, distributed between all four compounds (Fig. 3a, right). Nearly all of the rod-like inclusions are either liquid (NH₄)₂SO₄ or liquid H₂SO₄ (35 and 46‰ of cases in Fig. 3b). On the other hand, all columnar-like inclusions are solid CaSO₄⋅2H₂O (gypsum) (Fig. 3c). There are many inclusions with no Raman peaks, with 56% of them being the particle-like inclusions and the remaining 44% being the rod-like inclusions. The chemical composition of these inclusions is discussed next.

3.2.2 Shape and elemental components of nonvolatile inclusions in ice layers

The microscope observation method used above has the advantage of determining where the inclusions are located in an ice layer (e.g., within ice grains, along grain boundaries, in triple junctions). However, the method cannot detect all the inclusions because bubbles in an ice layer make it difficult to locate every inclusion. On the other hand, the sublimation–EDS method can measure the shapes and sizes of almost all inclusions formed in the ice layers.

The SEM measurements revealed 1230 nonvolatile inclusions in the three shape types through the 12 ice layers. Of these types, the particle-like inclusions occur in almost all ice layers and account for 94.4% (n = 1161) of the total inclusions (light and dark blue bars in Fig. 4b). Almost all rod-like inclusions occur in just the two thickest ice layers, though they account for 3.1% (n = 38) of the total inclusions (pink and red bars in Fig. 4b). The columnar-like inclusions exist in both thin and thick ice layers, but account for only 2.5% (n = 31) of the total inclusions (light and dark green bars in Fig. 4b).

Fig. 4.

Depth profiles of composition and inclusion type, as well as the elemental compositions in the nonvolatile inclusions. Analyses cover the surface snow and selected ice layers (Raman: 5 layers; SEM & EDS: 12 layers). (a) The number of times the chemical composition is detected by Raman analyses. (b) The number of each type of nonvolatile inclusion detected by SEM. (c) The number of times the element combinations are detected by EDS analyses in nonvolatile inclusions.

The cross-sectional area S (μm²) of an inclusion is measured by tracing the inclusion's perimeter on a photomicrograph. For the particle-like inclusions, we then calculate the radius r (μm) as

(1)$$\matrix{ {r = \sqrt {\displaystyle{{\rm S} \over {\rm \pi }}} \;} \cr } $$

We then define the grain diameter as twice the radius. For rod-like and columnar-like inclusions, the grain length is defined as the major axis. We refer to the grain diameter and length as D_inclusion (μm).

The two methods (microscope and SEM) similarly find the particle type to be relatively common and the rod type to be more common in thick ice layers. Moreover, both methods show columnar to be the least common type. The proportion of particle-like is much larger in the SEM method than in the microscope method. The difference is likely due to the particle-like inclusions being generally smaller (see below) and more easily detected with the SEM method. In addition, the rod-like inclusions with small D_inclusion (e.g., Fig. 8a, see ‘(X)’) are difficult to distinguish from particle-like inclusions in the SEM method, so some rods may have been counted as particle type.

Almost all nonvolatile inclusions in the surface snow sample at the site are particle-like (Fig. 4b), with an average grain diameter of 9.0 ± 8.7 μm. Also, nearly all inclusions in the surface snow are smaller than 30 μm in diameter, with 66% being smaller than 10 μm. These particle types and sizes are consistent with nonvolatile inclusions in dry snow and ice cores in Antarctica and Greenland analyzed previously with the sublimation method (Iizuka and others, Reference Iizuka2012a, Reference Iizuka2012b, Reference Iizuka2013; Oyabu and others, Reference Oyabu2014, Reference Oyabu2015, Reference Oyabu2020). Given that aerosols are generally less than 30 μm in diameter (e.g., Whitby, Reference Whitby1978), we conclude that the inclusions greater than 30 μm in diameter formed by refreezing meltwater. So, we divide the inclusions further into two size categories: smaller and larger than 30 μm in diameter. For particle-like inclusions, 22% are greater than 30 μm in diameter (dark blue bar in Fig. 4b). For rod-like inclusions, this percentage is 87% (red bar in Fig. 4b), whereas for columnar-like inclusions, the percentage is 61% (dark green bar in Fig. 4b). Thus, most rod-like and columnar-like inclusions are over 30 μm in diameter, and therefore likely formed by refreezing.

The elemental analyses of the nonvolatile inclusions in the surface snow sample and 12 ice-layer samples are shown in Figure 4c. We do not discuss Mg because its abundance is very small (5%). Additionally, we do not discuss Al because it is mainly in dust (insoluble terrestrial materials), which has Si as the main component. As a result, we classified the content of the inclusions into 12 categories based on their constituent elements of Na, Ca, S, and Cl, which are associated with Na⁺, Ca²⁺, SO₄²⁻, and Cl⁻ species. For example, inclusions containing all of Na, Ca, S, and Cl are classified as ‘Na∩Ca∩S∩Cl’. Those with Na and S but without Ca nor Cl are classified as ‘Na∩S’. Those with only S or only Cl are classified as ‘only S or Cl’. Finally, ‘Others’ have neither S nor Cl. (Others mainly contain Si, suggesting silicate minerals.) In the surface snow sample, 36% of the inclusions are classified as ‘Na∩S’, and nearly all of the remaining are ‘Others’ (Fig. S1a). Compared to the surface snow, inclusions in the ice layers contain much more ‘Na∩Ca∩S∩Cl’ (dark blue; 11%), ‘Na∩S∩Cl’ (dark red; 11%), and ‘Na∩Cl’ (dark green; 10%), and much less ‘Na∩S’ (light pink; 5%) (Fig. S1b). These differences are more pronounced in the larger inclusions (Fig. S1c). So, the combination of ‘Na∩Cl’ with or without S and Ca is common in the inclusions, particularly those formed by refreezing. The meltwater contains Cl⁻ (4.97 μeq L⁻¹) and Na⁺ (4.07 μeq L⁻¹) with a few SO₄²⁻ (2.85 μeq L⁻¹) and Ca²⁺ (1.28 μeq L⁻¹), and these ions are considered to aggregate as brine or salt during the refreezing.

The most common signal in the particle type is ‘Others’ (grey; 42% in Fig. 5a). Most of the ‘Others’ inclusions contain Si without Na, Ca, S, and Cl, suggesting that the particle-like inclusions mainly consist of mineral dust. The ‘only S’ inclusions may be NH₄⁺ and SO₄²⁻ as liquid brine because Raman measurements showed the liquid 982 cm⁻¹ peak, not the solid 975 cm⁻¹ peak. In this case, liquid brine may exist at the ice temperature of −18.9°C due to the eutectic temperature of (NH₄)₂SO₄ being −19.0°C, or due to an ion balance of SO₄²⁻ ≫ NH₄⁺ (Fig. S2c).

Fig. 5.

SEM-EDS analyses. (a) Particle-like inclusion from the 2012 ice layer and composition of 1161 particle-like inclusions from EDS analyses. (b) Rod-like inclusion from the 2012 ice layer and composition of 38 rod-like inclusions. (c) Columnar-like inclusion from the 2006 ice layer and composition of 31 columnar-like inclusions.

In contrast, the ‘Na∩Cl’ with or without S and Ca inclusions are considered to be salt mixtures of NaCl, Na₂SO₄, and CaSO₄. The Na₂SO₄ and CaSO₄, having eutectic temperatures of −1.3 and −0.05°C, are likely to exist as solid salts, whereas the NaCl, having a eutectic temperature of −21.3°C, can exist as a liquid brine of Na⁺ and Cl⁻ at −18.9°C. Thus, by combining the Raman and EDS analyses, we argue that the particle-like inclusions contain various solid salts of Na₂SO₄⋅10H₂O and CaSO₄⋅2H₂O, as well as brines of Na⁺, Cl⁻, NH₄⁺, and SO₄²⁻.

The primary category for rod-like inclusions is ‘Na∩Ca∩S∩Cl’ (dark blue; 45% in Fig. 5b). On the other hand, the Raman measurements show that the rod-like inclusions have mostly broad peaks of 982 and 984 cm⁻¹ (35 and 46% in Fig. 3b), as well as a high fraction of nonpeak-detected inclusions. The broad 982 and 984 cm⁻¹ peaks suggested that inclusions have NH₄⁺ and SO₄²⁻ (Fig. S2c), whereas the high fraction of nonpeak-detected inclusions suggests an ionic compound of Na⁺ and Cl⁻. Sakurai (Reference Sakurai2010) showed that mixtures of Na₂SO₄ and HCl have an extremely low eutectic temperature of −42.7°C (Na₂SO₄: 4.3 wt%, HCl: 2.1 wt%), which is colder than that of the Raman measurements (−30°C). Thus, a possible chemical form of the rod-like inclusions is a brine of SO₄²⁻, Cl⁻, Na⁺, and NH₄⁺.

For the columnar-like inclusions, the main elemental component is ‘Ca∩S’ (green; 55% in Fig. 5c). Thus, the columnar-like inclusions probably consist of CaSO₄. Also, their shape is consistent with the crystal structure of gypsum (CaSO₄⋅2H₂O), which is the prismatic class of the monoclinic system. These results suggest that the columnar-like inclusions contain impurities with the components of CaSO₄, which is consistent with the results from Raman analyses that indicated that the columnar-like inclusions contain solid gypsum salts (CaSO₄⋅2H₂O).

3.3.1 The refreezing processes of the two thick ice layers

Consider first the ice layer formed in 2012. Figure 6 shows its structure analyzed to 10 mm resolution. In (a), the values of δ ¹⁸O and δD vary by 2.1 and 17‰, respectively. According to previous studies (e.g., O'Neil, Reference O'Neil1968), these values are consistent with meltwater refreezing. δ ¹⁸O and δD have a correlation (Craig, Reference Craig1961), and Dansgaard (Reference Dansgaard1964) defined the deuterium excess (d−excess) as the following:

(2)$$d-excess = {\rm \delta D}-{\rm \;}8{\rm \;}{\rm \delta }^{18}{\rm O\;}$$

Fig. 6.

Depth profiles of the thick ice layer formed in 2012. (a) δ ¹⁸O, δD, d-excess, and major ion species (SO₄²⁻, Cl⁻, NH₄⁺, Na⁺, Ca²⁺). (b) The number of times the chemical compositions are detected by Raman analyses. (c) The number of inclusions of various types. (d) The number of times elements are detected by SEM analyses. Yellow bands are levels that likely froze last.

Lacelle (Reference Lacelle2011) suggests that the last ice to freeze is likely to have a higher d-excess value, such as that at depths ~ 4.370–4.390 m and 4.430–4.450 m, which we mark light yellow in the depth profiles. Hence, we believe that the 2012 ice layer is formed by at least three refreezing cycles.

We show similar analyses for the 2006 ice layer in Figure 7. (Inclusions above 6.071 m depth and below 6.191 m depth are not analyzed here due to the lack of water isotope data in those regions.) In (a), the values of δ ¹⁸O and δD fluctuate by 1.2 and 6.9‰, respectively. The slope of δ ¹⁸O and δD is 5.6, suggesting that the ice was formed by the refreezing of meltwater (e.g., Jouzel and Souchez, Reference Jouzel and Souchez1982; Souchez and Jouzel, Reference Souchez and Jouzel1984; Souchez and de Groote, Reference Souchez and de Groote1985). We consider the 6.101–6.126 m depths as the last region to freeze, due to the low δ ¹⁸O and high d-excess there, which are marked in light yellow in Figure 7. We believe that at least two refreezing cycles formed the 2006 ice layer.

Fig. 7.

Same as Figure 6, except from the ice layer formed in 2006.

Ion concentrations of all species are relatively high at the depths to freeze last (Figs 6a, 7a). For the 2012 ice layer (~ 4.370–4.390 and 4.430–4.450 m depths), each ion concentration is 1.1–1.8 times higher than that of other depths (Table 2). For the 2006 ice layer, each ion concentration except NH₄⁺ (μeq L⁻¹) in the last region of refreezing (~ 6.101–6.126 m) is also 1.1–1.4 higher than other depths (Table 2). As ice rejects impurities upon freezing (e.g., Halde, Reference Halde1980; Takenaka and others, Reference Takenaka1996), ionic materials in the thick ice layers should be concentrated in the last ice to freeze.

Table 2.

The average of major ion concentrations (μeq L⁻¹) in the thick ice layers of 2012 and 2006

^a Last regions to freeze.

3.3.2 Formation mechanism of inclusions during the refreezing processes of the two thick ice layers

The number and size of inclusions in the last region to freeze gives clues to their formation mechanism. To show the spatial distribution of inclusions for the example in the last region of the 2012 ice layer (4.370–4.390 m), we present Fig. S3. For all inclusions in the entire 2012 ice layer, the SEM measurements give the number n and average diameter φ of 574 and 36 ± 99 μm. Considering just the last two regions to freeze (4.370–4.390 m and 4.430–4.450 m), the n and φ are 311 and 34 ± 115 μm. For the entire 2006 ice layer, these values are 224 and 37 ± 78 μm. At the last region of refreezing in the 2006 layer (6.101–6.126 m), the values are 143 and 32 ± 45 μm. Table 3 shows the average diameter (μm) and areas (μm²) of three types of inclusions in the last region of refreezing in the 2012 and 2006 ice layers. Because of long length, the average diameters and areas of the rod-like inclusions are much larger than those of the particle-like and columnar-like types. For the last refreezing of 2012 and 2006 ice layers, the large rod-like inclusions are abundant (red bar in Figs 6c, 7c; red frame on box in Fig. S3). In the 2012 ice layer, 64% of the total rod-like inclusions over 100 μm in diameter occur (n = 7) in the last ice to freeze (4.370–4.390 m and 4.430–4.450 m). In the 2006 ice layer, 45% (only 5) of total rod-like inclusions over 100 μm in diameter occur in the last ice to freeze (6.101–6.126 m).

Table 3.

Average of diameters (μm) and areas (μm²) of inclusions in the last stage of refreezing in the 2012 and 2006 ice layers, according to the SEM analysis

Figure 8 shows the photomicrographs of the last region of refreezing in the 2012 and 2006 ice layers. The arrows in the micrographs (Figs 8a, 8b) show inclusions observed in the ice grains or grain boundaries. The rod-like inclusions are found here along grain boundaries (e.g., Fig. 8a X and Y, 8b Z), mostly in the last regions of refreezing. In the 2012 ice layer, the largest ones are about 150 μm long and 7.8 μm wide (Fig. 8a Y), and for the 2006 ice layer, they are about 500 μm long and 15.8 μm wide (Fig. 8b Z). As such, they are much wider than the other filaments in ice cores that never experience melting (e.g., Baker and others, Reference Baker, Cullen and Iliescu2003). The columnar-like inclusions instead are found within the ice grain (e.g., Fig. 8a arrow 4 and 8b arrow 6), whereas the particle-like inclusions (e.g., Fig. 8a arrow 1 and 8b arrow 7) are found both on the grain boundary and within the ice grain.

Fig. 8.

Photomicrographs and Raman spectra of inclusions. (a, b) Photomicrographs of regions within 4.370–4.380 m (last region to freeze) in the 2012 ice layer (a) and 6.116–6.121 m (last region to freeze) in the 2006 ice layer (b). The left edge is shallower depth, right edge deeper. ‘TJ’ indicates a triple junction. Green arrow is a particle-like inclusion of double salts of Na₂SO₄⋅10H₂O and CaSO₄⋅2H₂O within an ice grain. Orange arrows are liquid particle- and rod-like inclusions of (NH₄)₂SO₄ in grain boundaries. Red arrows: similar to orange arrows except H₂SO₄. Blue arrows are columnar-like inclusions of CaSO₄⋅2H₂O in the ice grain. The purple arrow is a particle-like inclusion of H₂SO₄ and CaSO₄⋅2H₂O in the triple junction. White arrows mark particle- and rod-like inclusions at grain boundaries or ice grains that have no Raman peaks detected. The black lines show a smaller rod-like inclusion (X) and larger rod-like inclusions (Y and Z). (c) Raman spectra of inclusions marked in (a) and (b).

With regard to the inclusion compositions, the Raman measurements (see section 3.2.1) indicate that particle-like types have a brine of NH₄⁺ and SO₄²⁻ (orange and red arrows in Figs 8a, 8b) as well as salts of Na₂SO₄⋅10H₂O (s) and CaSO₄⋅2H₂O (s) (green arrow in Fig. 8a). The columnar-like types have salts of CaSO₄⋅2H₂O (s) (blue arrows in Figs 8a, 8b). Additionally, the rod-like types have a brine of NH₄⁺ and SO₄²⁻ (orange and red arrows in Figs 8a, 8b). However, in the 2012 ice layer, 65% of the Raman measurements of rod-like inclusions in 4.370–4.390 m, one of the last regions to freeze, show no significant peaks (60% for section 4.430–4.450 m). Similarly, in the 2006 ice layer, 55% of the rod-like inclusions in the last region of refreezing show no significant peaks. These rod-like inclusions are marked by white arrows in Figures 8a and b. The lack of peaks is consistent with the rod-like inclusions containing Cl⁻ and Na⁺ as described in section 3.2.

In considering how an inclusion's composition relates to its size, we examined the relationship between the atomic fractions of Na, S, Cl, and Ca on the inclusion's cross-sectional area. The sum of four fractions equals 1. For the inclusions in the last stage of refreezing, the fractions of Ca in Figure 9 decrease significantly as the inclusion areas increase. Similarly, the fractions of S decrease gradually in the 2012 ice layer (4.370–4.390 m) and 2006 ice layer. The fraction of Na also decreases gradually, reaching about 0.4 in the largest areas. For the 2012 ice layer (4.430–4.450 m), the fraction of Cl instead increases to about 0.5 as the areas increase (Fig. 9b). In contrast, in the 2012 ice layer (4.370–4.390 m) and 2006 ice layer, the fraction of Cl has no significant change. However, the fraction of Cl is probably the same as Na, since the fractions of S and Ca decrease to 0 as the inclusion areas increase. Given that the area of the rod-like inclusions tends to be large, these results suggest that large rod-like inclusions in the last region of refreezing consist mainly of Na and Cl elements, with relatively little S and Ca. As described above, the rod-like inclusions show no significant Raman peaks, consistent with a large amount of Na⁺ and Cl⁻ (brine) in the rod-like inclusions. On the other hand, S and Ca increase as the areas decrease.

Fig. 9.

The fractions of Na (red), S (green), Cl (blue), and Ca (black) of a given inclusion and the inclusion area (μm²) for inclusions formed in the last region of refreezing. Also shown are the least-square-error straight-line fits for each element. Each of correlation coefficient (r) and p-value are in the box. Inclusions without Na, S, Ca, and Cl have mainly Si. We consider them as insoluble inclusions and do not plot them here.

Generally, the impurities in water concentrate in the liquid phase during freezing, with a tendency to collect in the triple junctions in the last region of freezing (e.g., Takenaka and others, Reference Takenaka1996; Bartels-Rausch and others, Reference Bartels-Rausch2014). The waterfront pressed the brine further down until the porosity or cold front prevents further progress. Then the brine is more concentrated and preserved as rod-like inclusions along the resulting grain boundary or triple junction. Thus, the redistribution of impurities can be explained by fractionation between solid and liquid impurities during the freezing. We summarize the proposed process in Figure 10: (a)–(b) The smaller columnar- and particle-like inclusions of solid Na₂SO₄⋅10H₂O and CaSO₄⋅2H₂O form in the ice grains. (c) Particle-like inclusions of brines with Na⁺, Cl⁻, NH₄⁺, and SO₄²⁻ form in grain boundaries. (d) Finally, if sufficient impurity exists in the meltwater, large rod-like inclusions of brines with Na⁺, Cl⁻, NH₄⁺, and SO₄²⁻ form at grain boundaries. In this way, when the ice layer is particularly thick, as is the case with the 2012 and 2006 ice layers, the grain boundaries can have particularly large rod-like brine inclusions.

Fig. 10.

Proposed formation mechanism of inclusions at the last region of refreezing in the two thick ice layers. The sequence of inclusion formation is summarized in the last (green-framed) drawing. White lines are grain boundaries or triple junctions.

3.3.3 Ion amount needed to form a large rod-like brine inclusion

To form a large rod-like brine inclusion, a certain amount of ion flux is needed. The major ion species in a large rod-like brine inclusion are Na⁺ and Cl⁻ (Fig. 9). To evaluate the ion amount, three parameters should be considered: (i) the concentration of impurities in the precipitation, (ii) how ion levels change as the meltwater percolates to the ice layer, and (iii) enrichment in the liquid phase during refreezing. As an example, we consider the large rod-like inclusion in 2012 (Fig. S3a-(1)) with the inclusion size as a cuboid of about 1600 μm in diameter and about 50 μm in width. The elemental mass ratios of Na and Cl compared to all seven elements (Si, Al, S, Cl, Na, Mg, and Ca) are 15.9 and 19.0%, respectively. With these numbers, we estimate that the inclusion contains 1.6*10⁻⁶ g Na and 1.9*10⁻⁶ g Cl.

For (i), the concentration of impurities in the precipitation, Na⁺ and Cl⁻ have average concentrations of 4.51 and 5.29 μeq L⁻¹, respectively, averaged over the entire core (Fig. 1). For (ii), the percolation process, the median values of the ion flushing ratio to ice layers from the upper firn are 1.26 for Na⁺ and 1.41 for Cl⁻, respectively (Fig. 2). Multiplying the ratio by the original concentrations, any ice layer in this ice core should have a potential of about 5.66 and 7.47 μeq L⁻¹ for Na⁺ and Cl⁻ before refreezing.

Finally, we evaluate (iii), enrichment in liquid phase during refreezing. To aggregate the estimated 1.6*10⁻⁶ g Na in the inclusion from the initial water concentration of 5.66 μeq L⁻¹, 12.31 g of water is required. For Cl, 7.17 g of water is required. Assuming uniform freezing in one direction as sketched in Fig. S4, the thickness of ice needed for the Cl case is about 7 cm.

This threshold thickness should depend on characteristics of the core, but in this case, the value is roughly consistent with nearly all rod types found in the 15.0 and 15.5 cm thick layers of 2012 and 2006 except those in thin ice layers. For example, in the earlier warm period of the 1920s, the thickest ice layer was 0.7 cm, and here we chose a 0.5 cm ice layer at random and detected in it no rod-like inclusions.