Abstract
<strong class="journal-contentHeaderColor">Abstract.</strong> Remote-sensing records over the last 40Â years have revealed large year-to-year global and regional variability in Antarctic sea ice extent. Sea ice area and extent are useful climatic indicators of large-scale variability, but they do not allow the quantification of regions of distinct variability in sea ice concentration (SIC). This is particularly relevant in the marginal ice zone (MIZ), which is a transitional region between the open ocean and pack ice, where the exchanges between ocean, sea ice and atmosphere are more intense. The MIZ is circumpolar and broader in the Antarctic than in the Arctic. Its extent is inferred from satellite-derived SIC using the 15â%â80â% range, assumed to be indicative of open drift or partly closed sea ice conditions typical of the ice edge. This proxy has been proven effective in the Arctic, but it is deemed less reliable in the Southern Ocean, where sea ice type is unrelated to the concentration value, since wave penetration and free-drift conditions have been reported with 100â% cover. The aim of this paper is to propose an alternative indicator for detecting MIZ conditions in Antarctic sea ice, which can be used to quantify variability at the climatological scale on the ice-covered Southern Ocean over the seasons, as well as to derive maps of probability of encountering a certain degree of variability in the expected monthly SIC value. The proposed indicator is based on statistical properties of the SIC; it has been tested on the available climate data records to derive maps of the MIZ distribution over the year and compared with the threshold-based MIZ definition. The results present a revised view of the circumpolar MIZ variability and seasonal cycle, with a rapid increase in the extent and saturation in winter, as opposed to the steady increase from summer to spring reported in the literature. It also reconciles the discordant MIZ extent estimates using the SIC threshold from different algorithms. This indicator complements the use of the MIZ extent and fraction, allowing the derivation of the climatological probability of exceeding a certain threshold of SIC variability, which can be used for planning observational networks and navigation routes, as well as for detecting changes in the variability when using climatological baselines for different periods.
Highlights
The Southern Ocean holds the largest circumpolar marginal ice zone (MIZ) in the world ocean (Weeks, 2010, p. 408), while in the Arctic MIZ features are mostly confined to the Bering Sea and the Greenland and Norwegian Seas (Wadhams, 2000)
Since the interest is in identifying the typical conditions differentiating the MIZ from more consolidated and less variable sea ice concentration, the median of the indicator computed for each pixel is a useful descriptor of the most common spatial 145 features (Fig. 2a)
The Antarctic marginal ice zone is characterised by highly variable sea-ice features in terms of texture, thickness and combi270 nation of ice types during its seasonal evolution
Summary
The Southern Ocean holds the largest circumpolar marginal ice zone (MIZ) in the world ocean (Weeks, 2010, p. 408), while in the Arctic MIZ features are mostly confined to the Bering Sea and the Greenland and Norwegian Seas (Wadhams, 2000). The MIZ is a transitional region, and as such, it is often defined by contrasting consolidated pack ice and open ocean conditions. This implies the identification of two boundaries, one at the ice-ocean margin and one within the pack ice. The ocean edge and the 20 MIZ extent are inextricably linked, since it is difficult to find sharp separations between these two realms.
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