Melt pond size and shape evolution

Many processes control the development of melt ponds. Considered as a hydraulic unit, a melt pond can be presented as a surface water body determined by the balance of inflows and outflows, distributed in local depressions. Previous observations concluded that the evolution of melt pond is characterized by four distinct stages, based on the pond behavior and control mechanisms (Eicken and others, Reference Eicken, Krouse, Kadko and Perovich2002; Polashenski and others, Reference Polashenski, Perovich and Courville2012).

Given the temporal evolution, the mechanisms governing the pond geometry are quite complicated and multiple-factor controlled, such as, ice/snow topography, pond sidewall and bottom ablation, ice permeability, balance between inflows and outflows, and occasionally, precipitation and changing weather conditions. Seeing that understanding melt pond evolution remains a significantly challenging task, a question is whether there are some universal characteristics of pond geometry not depending upon the details of the driving mechanisms. A simplified fractal geometry method is employed here (see Hohenegger and others (Reference Hohenegger, Alali, Steffen, Perovich and Golden2012)). The geometrical features of melt ponds and the complexity of their shorelines can be quantified by the fractal dimension D _A derived from S ~ P data, which are usually used to determine the fractal dimension of lake group, other than the box-counting method in the section ‘Pond shape’, defined as

$$\eqalign{P &= k\sqrt S ^{D_{\rm A}} \quad {\rm with}\quad k \gt 0,\;{\rm then} \cr \log P &= \displaystyle{{D_{\rm A}} \over 2}\log S + \log k,} $$

where P and S denote the perimeter and area of a melt pond, respectively. k is a constant. On log/log scales, the slope characterizing the S ~ P data is one half of the fractal dimension. The logarithmic area–perimeter data are plotted in Figure 8 for all melt ponds counted in Figure 4. Our analysis of these data sets indicates that MYI and FYI melt ponds are similar with respect to the perimeter/area relation (i.e. fractal dimension), and both trends change slopes similarly around a critical length scale of ~100 m² in area, in favorable agreement with findings by Hohenegger and others (Reference Hohenegger, Alali, Steffen, Perovich and Golden2012).

Fig. 8.

Area-Perimeter data for melt ponds on FYI (a) and MYI (b) displays a ‘bend’ around a critical length scale of 100 m² in area. Red lines indicate the general trends in each subregions. The types (FYI or MYI) of the floes are judged visually and empirically based on their size, color, surface topography (smooth or rough with ridges), location and general ice conditions derived from ship-based ice observations (Xie and others, Reference Xie2013).

Approximately, at the beginning of melt pond formation (i.e. stage I nominated by Polashenski and others, Reference Polashenski, Perovich and Courville2012), shallow ponds emerge on the ice surface, with rather small ponds on MYI but more extensive on FYI. These initial ponds are somewhat circular in shape and their boundaries are simple Euclidean curves with fractal dimension D _A≈ or close to 1 (Fig. 9a). As the melt period progresses, these ponds grow both in area and depth (Morassutti and LeDrew, Reference Morassutti and LeDrew1996; Perovich and others, Reference Perovich2003) due to rapid meltwater inflows, pond wall and bottom ablation, and limited outflow pathways. As the pond coverage and depth increase, these small isolated ponds may coalesce to form clusters (Fig. 9b), which themselves coalesce to simple and/or single dendritic ponds (transitional ponds) just spanning the image (Fig. 9c) with 1 < D _A < 2, and then fully connected pond networks of much complex shape with D _A≈ or close to 2 (Fig. 9d), most of which actually melt through. During every stage of melt pond evolution (Eicken and others, Reference Eicken, Krouse, Kadko and Perovich2002; Polashenski and others, Reference Polashenski, Perovich and Courville2012), pond size and shape vary tremendously in location, melting duration, wind force, floe topography, physics and permeability, from isolated small ponds of regular shape to interconnected networks of complex shape.

Fig. 9.

Evolution of melt pond shape and connectivity. (a) Simple disconnected ponds, (b) ponds extending and starting coalescing to form clusters, (c) mature networks of ponds, (d) dense networks of connected and fully melt-through ponds, the floe would disintegrate by slight wind or flow disturbances. Note that not all shaping stages are expected to take place anywhere. The final stage of pond evolution may vary regionally, and depends on the ice type, latitude and prevailing atmospheric forcing.

These results, with Hohenegger and others (Reference Hohenegger, Alali, Steffen, Perovich and Golden2012), demonstrate that there is a separation of length scales in melt pond structure. Pond complexity increases rapidly through the transition as smaller ponds coalesce to form large connected regions, and may reach a maximum for ponds larger than 1000 m², whose boundaries resemble space-filling curves, with D _A ≈ 2. This scaling separation in pond geometry can ultimately lead to more realistic and efficient treatments of melt ponds and melting processes in climate models. For instance, a scaling separation in the microstructure of an inhomogeneous composite medium (melt pond-sea ice) is a necessary condition in numerous homogenization schemes (also known as upscaling) to estimate its overall or effective properties and behaviors, such as floe albedo and light transmission through ponds and its influences on the heat budget of the upper ocean and biological productivity. A large developed ramified pond network, usually spanning an ice floe, is inevitably more effective to contribute to breaking apart a floe than many small isolated ponds.

Moreover, according to the critical length scale for melt ponds, large-scale well-connected pond networks can be considered consisting of small-scale ponds of basic shapes. That is, each melt pond can be broken into basic parts of either thin elongated shapes (called bonds), or approximately convex shapes (called nodes). The structure of a melt pond can be described as a locally dendritic network of nodes joined together through bonds. A simple melt pond with D _A = 1 is a small network consisting of a single node or possibly a few connected nodes, while more complex melt ponds (1 < D _A < 2) are networks consisting of many nodes and bonds. Thus if we assume melt ponds are distributed randomly on the ice floe surface (i.e. homogeneous medium), a universally stochastic model can be proposed for melt pond distribution on the basis of the area-number power-law relationship as shown in Figure 5. This can lead to more realistic and efficient parameterizations for ice floe albedo, radiation transmittance and light field in the upper ocean layer.

Implications for heat transport within pond and heterogeneity of under-ice light field

During summer, Arctic sea ice is a complicated, changing mosaic of ice/snow, melt ponds and open water. This morphological diversity has considerable impacts on the reflection, absorption and transmission of solar energy in ice-ocean system. The large differences in light reflectance from melt ponds, bare ice/snow, and leads, and the integrated surface albedos, have been well documented by in situ instrumentation, remote sensing technologies and mathematical models. The areal fraction data of sea ice surface types presented in this paper can be used to estimate the albedos of the investigated regions assuming arbitrary values for each surface type. These datasets can also validate and assess recently developed algorithms for retrieving melt pond fraction from air- and space-borne optical sensors (Rösel and others, Reference Rösel, Kaleschke and Birnbaum2012; Istomina and others, Reference Istomina2014).

Due to more solar energy absorbed by melt ponds, explicitly horizontal and vertical heat transports within ponds, i.e. the heat flux into sidewall for lateral expansion and into bottom for deepening, are needed to be quantified in modeling melt pond evolution, because the bottom and lateral ablation of melt pond is one of the pivotal and durative processes affecting the area and depth of melt pond, hence the surface albedo and vertical radiation through ponds into the underlying ice and ocean (Fig. 10). Typically melt ponds are shallow (depth < 40 cm) with salinity <5 PSU. Natural convection in the pond rapidly causes mixing that eventually forces an equilibrium temperature with slight wind forces, and even without winds (Skyllingstad and Paulson, Reference Skyllingstad and Paulson2007; Huang and others, Reference Huang, Li, Wang and Lei2011). By using a simple large eddy model with high-resolution turbulence simulation, Skyllingstad and Paulson (Reference Skyllingstad and Paulson2007) argued that the in-pond horizontal and vertical current circulations control the horizontal and vertical heat transport into the sidewall and bottom, and determine the significant impacts of pond geometry on pond turbulences and thus on pond growth rates and albedo. The basic ratio R _sb of sidewall area to bottom area could be considered as a combining indicator for a variety of pond shapes and sizes, and could be deployed to characterize turbulence transfer rates and melting rates for ponds of simple shapes. Ponds with larger R _sb would generally melt more rapidly in horizontal direction at the expense of bottom melting, and tend to reduce turbulence transfer rates. Accordingly, ponds with small size, with enlongated boundaries, or with quite convoluted edge lines would have a relatively larger lateral growth rate compared with large, symmetric ponds. The melt pond geometry metrics and its size-evolution data presented by this paper provide a sound ground truth and initial forcing for their bulk pond model. For instance, assuming an arbitrary depth for our ponds (actually field data or an empirical equation would be the best), the ratio R _sb can be determined from Figures 6, 8b, the shapes of melt ponds with varying sizes can be simplified as regular outlines (circular, rectangular, channel, or their combination) (Hohenegger and others (Reference Hohenegger, Alali, Steffen, Perovich and Golden2012) with zigzags of different scale following the approach developed by Skyllingstad and Paulson (Reference Skyllingstad and Paulson2007). The serrating of pond boundaries is to satisfy the values of R _sb, convex degree, or fractal dimension manifested in Figure 7. With these settings, the bulk model of melt pond evolution can run with atmospheric forcing (e.g. remote sensing data) to simulating the evolution of pond size and depth, hence a more precise scheme of albedo in climatological models. Also, our data can be used to validate and evaluate the model results. Undoubtedly, a sophisticated parameterization of ponds and albedo also requires more additional data such as detailed information on albedos of ponds of different depth and sea ice topography; and a great number of efforts are still needed to quantify the melt pond geomorphology and energy budget evolution.

Fig. 10.

Conceptual model of solar radiation partitioning in melt pond/ice matrix and heat transport induced by turbulences within ponds. The size and shape of melt pond influence the horizontal and vertical heat transport induced by the water turbulences (Skyllingstad and Paulson, Reference Skyllingstad and Paulson2007). The significant differences in transmitted light under ponded ice and bare ice/snow lead to a remarkable heterogeneity of solar radiation in the upper ocean (T _p is ~4–5 times higher than T _i) (Ehn and others, Reference Ehn2011).

The universal ice thinning and the emerging shifts from perennial to seasonal ice are reducing the reflection of solar irradiance by ice cover, emphasizing an enhanced absorption and transmission of the melt pond-sea ice system. Previous field campaigns indicated that the transmission of incident irradiance (especially for PAR band) through ponded ice was ~2–5 times larger than that through ambient bare melting ice (Perovich, Reference Perovich2005; Light and others, Reference Light, Grenfell and Perovich2008; Ehn and others, Reference Ehn2011). Nicolaus and others (Reference Nicolaus, Katlein, Maslanik and Hendricks2012) concluded that melt pond formation is the key process accounting for a distinctly larger transmittance and absorbance of FYI than those of MYI. Light transmission through the ice cover was not only a function of surface properties and ice thickness (at scale >1000 m²) but also of the size covered by a particular ice surface type like melt pond (Fig. 10), especially at a local scale (e.g. <1000 m²) (Katlein and others, Reference Katlein2015). Assuming the incident solar radiation and the ice thickness is regionally homogeneous, the geometric variability and spatial distribution of surface types (leads, bare ice and ponded ice) causes a significant spatial heterogeneity in transmitted light fields in the upper ocean, which plays a pivotal role in primary productivity (Mundy and others, Reference Mundy2009; Arrigo and others, Reference Arrigo2012), nutrient quality (Leu and others, Reference Leu, Wiktor, Soreide, Berge and Falk-Peterson2010) and even the outgassing of CO₂ (Spencer and others, Reference Spencer2009). For instance, the melt pond geometry are demonstrated to have significant effects on the transmitted light fields in under-ice water using a simple edge spread function model (Fig. 10) (Ehn and others, Reference Ehn2011). With our spatial distribution data of melt pond geometry (size and shape), the spatial heterogeneity of transmitted light field under continuous floes can be assessed with the model mentioned above. However, although a pan-Arctic model provides a promising estimate of heat flux through sea ice assigning constant values to different ice types (MYI/FYI) (Arndt and Nicolaus, Reference Arndt and Nicolaus2014), a lot of efforts have to be exerted to the investigations and quantification of the light transmittance, extinction, scattering and horizontal transport of melting sea ice, melt ponds and under-ice ocean water, and of the spatial distribution of ice thickness, ice properties (FYI or MYI), the proximity to each other surface types and even of the ice drift. A complicated 3-D radiative transfer model is also needed to represent the full spatial distribution of propagated light under natural surface conditions.