Introduction
Snow blankets some 98% of all surfaces in Antarctica, including the ice cover on the surrounding seas. The top layer is a seasonal snow cover, a term we use here to denote the snow cover deposited over the latest annual cycle. The properties of this seasonal snow cover need to be adequately represented in climate models (Reference Smith, Budd and ReidSmith and others, 1998; Reference Bailey and LynchBailey and Lynch, 2000a, Reference Bailey and Lynchb). The rate of cold air production is controlled by Antarctica’s snow-covered terrain which through its katabatic effects renders the downwelling of air into the Antarctic anticyclone much stronger than that in any of its high-latitude counterparts in the Northern Hemisphere (Reference Van den Broeke and BintanjaVan den Broeke and Bintanja, 1995). Both the radiative and the turbulent fluxes at the surface of a snow cover depend strongly on its surface roughness. This property too is a difficult one to assess, for snow surface roughness is directionally, spatially and temporally variable (Reference Bintanja and vanBintanja and Van den Broeke, 1995).
One way in which the snow-cover properties can be assessed spatially is by satellite remote sensing (Reference Orheim and LucchittaOrheim and Lucchitta, 1988, Reference Orheim and Lucchitta1990; Reference BindschadlerBindschadler, 1998). With only limited ground truth, however, it is often difficult to interpret the remotely sensed information. The way in which solar radiation is absorbed and reflected can be readily observed by satellite-based remote sensing, but it is known that the anisotropic reflectance properties of snow vary on both a daily and a more long-term basis (Reference WintherWinther, 1993). Similarly, our own preliminary observations show that the thermal emission from a snow surface is not necessarily isotropic. Repeat imaging by RADARSAT at the South Pole shows that microwave backscatter and, by extension, microwave emission can also be highly anisotropic (personal communication from K. C. Jezek, 1999).
The aim of our present work is to obtain baseline surface data on the properties of the snow cover and on how they vary spatially with environmental variables such as distance from the sea and altitude. To develop better knowledge of the wintertime snow conditions and of possible factors influencing radar backscatter, we also examine the internal structure of the snow cover. The present project, Seasonal Snow in Antarctica, was initiated for this purpose. The first field season took place during austral summer 1999/2000, as part of the Finnish Antarctic Research Programme (FINNARP). The measurements were continued during the 2000/01 season.
Methods And Study Area
Dronning Maud Land is part of East Antarctica, and the measurements were made in its western part, Maudheimvidda (Fig.1). Twomountain ranges are situated in the area. Vestfjella is a 130km longmountain range near the grounding line of the ice sheet flowing toward the Weddell Sea. Heimefrontfjella is situated about 150 km inland from Vestfjella. This mountain range partly blocks the ice flow from Amundsenisen. Riiser– Larsen is a small ice shelf, and Ritscherflya is the ice sheet between two mountain ranges. Blue-ice areas are common throughout the Vestfjella area (Reference Holmlund and NäslundHolmlund and Näslund, 1994). Kvitkuven is an ice rise and Högisen is an ice dome located in the area. According to previous studies, accumulation on the Riiser–Larsen Ice Shelf is 0.4 mw.e., and above the grounding line it is about 0.3 mw.e. (Reference Isaksson and KarlénIsaksson and Karlén, 1994b).
The location of the Finnish research station Aboa, the land routes used and variations in radar backscatter observed in the RADARSAT mosaic (Fig.1) determined our measurement sites. Snow-pit measurements were made along a 350 km transect from the seaward edge of the ice shelf to the Amundsenisen plateau (Fig. 1). Snow-pit coordinates are listed in Table 1. The snow cover on the land-fast sea ice was measured near the ice shelf (site 0). Themeasurements on the continent were made in 17 shallow snow pits with an average depth of about1.5m. Two sites were located on the local topographic highs, Kvitkuven and Högisen. At nine sites automated sensors were installed to measure temperature and snow-depth evolution through the winter. The snow-sensor data will be discussed elsewhere; here we will deal only with the results of the snow-pit investigations.
Western Dronning Maud Land has seen several snow studies in previous years. The history of accumulation measurements there, beginning in 1935, is given by Reference Isaksson and KarlénIsaksson and Karlén (1994b). Most recently, the Swedish Antarctic Research Programme (SWEDARP) and the European Project for Ice Coring in Antarctica (EPICA) have made accumulation and climate studies (Reference Isaksson and KarlénIsaksson and Karlén 1994a, Reference Isaksson and Karlénb; Reference Isaksson, Karlén, Gundestrup, Mayewski, Whitlow and TwicklerIsaksson and others, 1996; Reference Van den BroekeVan den Broeke and others, 1999; Reference KarlöfKarlöf and others, 2000; Reference SommerSommer and others, 2000). Snow distribution (Reference Richardson, Aarholt, Hamran, Holmlund and IsakssonRichardson and others, 1997) and snow chemistry (Reference StenbergStenberg and others, 1998) were studied from the coast to the polar plateau in the 1990s.
The present snow measurements consist of profiles of temperature, density, grain-size and shape, dielectric constant, wetness and electrical conductivity as well as of the number and position of ice layers, albedo and solar-radiation attenuation. At five sites a seasonal oxygen isotope ratio (δ18O) was determined. Most of the profiles were measured in situ at 5–10 cm intervals, but conductivity and δ18O were analyzed from melted samples. Conductivity measured using a hand-held conductivity meter and the conductivity data were used to estimate the salinity of snow on the sea ice. The oxygen isotope analysis was performed at the Laboratory of Isotope Palaeoclimatology, Tallinn Technical University, Estonia. Snow-pitmeasurements were made using the classical methods. Snow density and other sampling employed a cylindrical snow tube (500 cm3). Samples were weighed using a spring balance. Temperature profiles were measured using a resistance thermometer with a 0.1 mlong temperature probe. The snow-station installation required drilling to about 4.5 mdepth, and temperatures from the bottom were measured immediately upon extraction of firn cores. Snow grains were photographed using a special camera stand (Reference Pihkala and SpringPihkala and Spring, 1985), and grain diameter and shape were determined from the photographs. The dielectric constant was measured with a LEAS’s TEL051 dielectric probe. The relative permittivity is a complex quantity, where ɛ' and ɛ" are the dielectric constant and the dielectric loss factor (Reference Hallikainen, Winebrenner and CarseyHallikainen and Winebrenner, 1992). Surface albedo was measured with a Middleton EP16 pyranoalbedometer, sensitive from 300 to 3000 nm, measuring both downwelling and upwelling irradiance simultaneously. The spectral attenuation of solar radiation was measured using an ASD Personal Spectrometer II from 350 to 1050 nmin semi-infinite snow cover, i.e. snow of sufficient thickness that the measured signals are independent of the underlying surface (Reference Brandt and WarrenBrandt and Warren, 1993). To measure attenuation, a fibre-optic probe was inserted progressively into the snow, and spectra were acquired at approximately 10 cm intervals. The geographic positions of the measurement sites were determined by a hand-held global positioning system (Garmin) with an accuracy of ±100m.
Results And Discussion
Table 2 summarizes our measurements. Figure 2 displays the variations in first-metre mean values of grain-size, conductivity and number of ice layers with distance from the coast. The dielectric constants seen in Figure 2 are from the surface, and the low values seen in the graph are from the local topographic highs. The first value of the dielectric constant is from the snow on the sea ice. Grain-size was largest on the seaward edge of the ice shelf. Near the coast there were thick (1–5 cm) ice layers, but above the grounding line there were many thin (0.5–2mm) ice layers in the first metre of snowpack. On the Högisen ice dome there were no ice layers in the first metre of snow. The first value of conductivity is from the edge of the ice shelf. On the sea ice conductivity of snow was 3.9 mS cm–1.
Snow temperature, density and accumulation
Temperatures (depth 0–1m) show strong negative correlation with elevation (r = –0.92) and also with distance from the coast (r = –0.88). Daily temperature variations were significant down to about 30 cm depth. The temperature gradient in the interval 30–150 cm was –0.05°Ccm–1, and in the interval150–400cmwas –0.02°Ccm–1.
During the 1999/2000 season the mean density in the first metre with the standard error was 409 ± 8 kgm–3; on the ice shelf it was 427 ± 9 kgm–3 and on the local topographic highs it was 340 kgm–3. Only the density profiles from the ice dome and the ice rise had a clear increase of density with depth in the first 150 cm. According to Reference Kojima and MellorKojima (1964), surface density is typically about 300–400kgm–3, while at 10m density it is 500–600kgm–3. According to Reference Isaksson and KarlénIsaksson and Karlén (1994b), in 1989 the mean annual density in the same area from the coast to Heimefrontfjella was 412 kgm–3 and from Vestfjella to Heimefrontfjella it was 397 kgm–3. Reference Gjessing and WoldGjessing and Wold (1986) have measured densities in the uppermost 3m of the Riiser–Larsen Ice Shelf of 470–510 kgm–3. They also measured the lowest values at the top of the Kvitkuven ice rise. In Kemp Land in Antarctica snow densities of 398–438kgm–3 have been observed in the uppermost 2 m (Reference Goodwin, Higham, Allison and JiawenGoodwin and others, 1994).
The δ18O values, measured for five different sites, cover only slightly more than one annual cycle (Table 2). For such a short period, many errors are possible in the estimation of seasonal accumulation. For example, the surface roughness or micro-relief due to snow dunes and sastrugi can be equivalent to or greater than 1year’s snow accumulation (Reference Goodwin, Higham, Allison and JiawenGoodwin and others, 1994), so the annual cycle may be distorted, and the values may be biased by evaporation processes during snowdrifting. This may apply to the mean δ18O values in Table 2. The approximate annual accumulation, based on snow-pit and δ18O data, is also given in Table 2. The values are in good general agreement with previous accumulation measurements in the area (Reference Isaksson and KarlénIsaksson and Karlén, 1994a, Reference Isaksson and Karlénb; Reference Isaksson, Karlén, Gundestrup, Mayewski, Whitlow and TwicklerIsaksson and others, 1996). On Kvitkuven the accumulation was lower than on the ice shelf nearby. Reference Gjessing and WoldGjessing and Wold (1986) also concluded that the mean accumulation was lower on Kvitkuven than on the rest of the ice shelf.
Layering and snow grains
The snow cover contains numerous thin ice layers and crusts (0.5–2mm), which, according to Reference GoodwinGoodwin (1991), form at the surface in summer due to strong incident solar radiation and wind. Some subsurface melting occurs, but evaporation crusts dominate inland. Wind crust forms by the action of the wind on the surface. Because of low inland precipitation, the vertical distance between ice layers is small and there are many such layers in the first metre of the snowpack. Near the coast, summer melting and thick melt–freeze ice layers (1–5 cm) occur. The snowpack is layered also as a result of snow transport by the wind. According to Reference Mosley-Thompson, Kruss, Thompson, Pourchet and GrootesMosley-Thompson and others (1985), a high-density layer with fine grains forms in winter, while summer layers have lower density and bigger grains. Metamorphism is mainly caused by temperature gradient and diffusion of water vapour. Depth hoar is an annual phenomenon according to Reference Mosley-Thompson, Kruss, Thompson, Pourchet and GrootesMosley-Thompson and others (1985). Loose, big-grained depth-hoar layers were found usually beneath ice layers.
In Antarctica, snow grains are rounded at a very early stage because of wind fragmentation and radiation, and they can be classified as big well-rounded particles according to Reference ColbeckColbeck and others (1990). Near the coast there were also rounded polycrystals as a result of melt–freeze cycles. On Högisen (site 8), grains with fragments of relatively intact precipitation particles were found down to 60 cm depth. The snow in this location was less densely packed, being apparently less affected by katabatic winds. The average grain diameter over the entire transect was 1.5–2mm in the upper first metre and at the surface 1mm. In Figure 3, snow grains from measurement sites 1, 9 and 11 (Fig.1) can be seen. Site 1was located near the edge of the ice shelf. Grains from 20 cm depth are rounded polycrystals. Site 9 was located near the Basen nunatak, and well-rounded grains from that site are from 20 cm depth, representing the most common grain shape. Site 11 is located on Högisen. The photographs are from the surface and from 60 cm depth. Fragments of precipitation particles can still be seen. Dahe and others (1988) studied the growth rate of grains, and in the upper 5–7m observed values were about 1.5–3 times those below 5 m. They measured the grain area, which varied through 0.1–0.2mm2 close to the surface and 0.2 –3mm2 at 10 m depth. In Kemp Land, grain diameters varied from 0.7 to >2mm, with small near-surface grains and bigger depth-hoar crystals (Reference Goodwin, Higham, Allison and JiawenGoodwin and others, 1994).
Electrical properties
The surface dielectric constant was "0 =1.72 ± 0.05, while in the upper first metre it was 1.81 ± 0.02. In the snow on sea ice the dielectric constant was 2.9. The snow cover can contain liquid water at temperatures near 0°C, and this strongly affects its dielectric constant. Excepting the coastal areas in summer, the snow cover of Antarctica can be considered to be dry. The dielectric constant of snow also depends on its density and crystal shape (Reference Hallikainen, Winebrenner and CarseyHallikainen and Winebrenner, 1992). Our measured dielectric constants were related to snow density ρ (g cm–3) by "0 = 0.9 + 2.2ρ, which is close to the empirical formula "0 = 1.0 + 2.1» given by Reference Ulaby, Moore and FungUlaby and others (1986). The mean wetness expressed in per cent by volume was 0.9 ± 0.1%. The mean conductivity of the upper first metre was 7.7 ± 1.3 μS cm–1 if we leave out the edge of the ice shelf (site 1) where the value was considerably higher than elsewhere (Table 2).
In the 1997 RADARSAT mosaic from the Antarctic Mapping Mission (200m resolution) a significantly lower backscatter coefficient is observed for Högisen and Kvitkuven (Fig.1). Both are local topographic highs with less dense snow and a lower dielectric constant than was found elsewhere along our transect. The snow surface was smoother than in nearby valleys, apparently due to lighter wind action.
Radiation measurements
The albedo for the measured 10 sites on the glacier was 0.84 ± 0.01; for snow-covered sea ice the albedo was 0.77. Light penetration into the snow cover is important as it is indicative of the energy available to drive snow metamorphism, internal melt and photochemical processes within the snowpack (Reference Brandt and WarrenBrandt and Warren, 1993). For our analysis the spectral interval was limited to 400–900 nm as the signal-to-noise ratio was too low outside this interval. Transmission factors were estimated from the ratio of upwelling radiance at depth to the upwelling radiance at the surface, assuming Lambertian reflectance at all depths. For semi-infinite snow (Fig. 4) the attenuation is strongest in the top few centimetres of the snowpack and decreases exponentially with increasing depth. In the top curves, the attenuation is strongest in the near-infrared. Deeper into the snow, longer wavelengths are extinguished, as predicted and observed by Reference Brandt and WarrenBrandt and Warren (1993). The lowest attenuation occurs around 420–470nm. In Figure 5, extinction coefficients are computed using Bouguer–Lambert’s law for a wavelength of 470 nm at site 5. The extinction coefficient was averaged for the different depths sampled and the mean value was calculated. The hypothesis that the extinction coefficient decreases with increasing grain-size (Reference WarrenWarren, 1982) was evaluated. The extinction coefficient was averaged for every sampled depth and plotted vs the associated grain-size from snow-pit measurements. The correlation was found to be site-specific as seen in Figure 5. The mean extinction coefficient for semi-infinite snow was 0.11cm–1. This is in accordance with results by Reference LiljequistLiljequist (1956), Reference Grenfell and MaykutGrenfell and Maykut (1977) and Reference GrenfellGrenfell (1979).
Snow zones from coast to inland
According to our measurements, five snow zones can be suggested.
(1) The saline snow cover on sea ice is mostly thin, annual and has high conductivity (3.9 mS cm–1) and dielectric constant (2.9). The snow thickness at site 0 in this zone was 25 cm, the mean density was 413 kgm–3 and the mean salinity was 2 ppt. Flooding of sea water onto sea ice, capillary effects and redistribution of snow by wind cause the snow to become saline (Reference Granberg and LeppärantaGranberg, 1998). This modifies snow dielectric properties, grain-size distribution, melting point and the degree of bonding between ice and snow (Reference Massom, Drinkwater and HaasMassom and others, 1997). Our measurements were made in the middle of the warm season. Reference Worby, Massom, Allison, Lytle, Heil and JeffriesWorby and others (1998) report, based on results from two voyages in East Antarctic sea ice (May 1993 and August 1995), a mean snow density of approximately 400 kgm–3 and a mean salinity of 8.5 ±11.5 ppt. Studies in the Weddell Sea in mid-winter give a mean density of 320 ± 90 kgm–3 and a mean salinity of 8.68 ±10.7 ppt (Reference Massom, Drinkwater and HaasMassom and others, 1997).
(2) The seaward edge of the ice shelf experiences melting during the summer months. During the season low clouds were often observed locally near the edge of the shelf, giving a much less negative thermal radiation balance there than just a few tens of kilometres inland. This may contribute to a greater incidence of surface melt in this zone. Accordingly, the snow cover in this zone is very hard and dense, with higher conductivity than further inland and ice layers 1–5 cm thick, enabling identification of the summer layer. Generally, snow grains are larger in this zone than elsewhere.
(3) In the inner parts of the ice shelf some melting also occurs. The snow is hard and dense, with occasional thick ice layers. However, grain-size is smaller than near the seaward edge of the ice shelf.
(4) The snow above the grounding line and behind the first mountain range is not as hard and dense as on the ice shelf, and is more uniform in the vertical sense. Thin ice layers (0.5–2mm) are observed. The annual accumulation decreases with distance from the coast. In the measurement area the grounding line is situated close to the Vestfjella mountain range.
(5) The local topographic highs are an exception. The snow surface is smoother and the snow has a lower density and dielectric constant. There are very few ice layers, and precipitation particles keep their form. Local topographic highs channel the katabatic outflow and are not as strongly affected by katabatic winds as nearby glaciers.
Conclusions
Spatial variations in physical properties of the snow cover have been measured from the coastal region to the polar plateau along a 350 km line. Measurements were made in shallow snow pits using classical methods. Generally on the ice shelf the snow cover was more layered compared to more uniform snow above the grounding-line area.
Snow-pit studies suggested five principal snow zones in the measurement area. Annual, thin and saline (2 ppt) snow on sea ice has high conductivity (3.9mS cm–1) and dielectric constant (2.9). On the seaward-edge zone of the ice shelf, summer melting occurs, forming dense snow with thick ice layers (1–5 cm) and big polycrystals (5mm). Snow near the edge of the ice shelf has higher conductivity (99.9 μS cm–1) and dielectric constant (2.1) than further inland. In the inner parts of the ice shelf, snow is hard and dense, and occasionally some thick ice layers occur. On the ice shelf, snow is denser (427± 9 kgm–3) than behind the first mountain range. The snow cover above the grounding line was more uniform, having thin ice layers (0.5–2mm) instead of thick ones. Surface slope in the grounding-line area reduces precipitation and accumulation inland (Reference BromwichBromwich, 1988). Accumulation varied from approximately 340 to 100 mmw.e. from the seaward edge of the ice shelf to the polar plateau. Local topographic highs differ most from the other snow environments, having smoother surface, less dense snow (340 kgm–3) and lower dielectric constant (1.4) compared to nearby glaciers.
Based on data for only one season it is difficult to say if these snow zones recur every year. Seasonal snow properties depend strongly on meteorological factors, notably wind and solar radiation, but the uniqueness of Antarctic snow is probably first related to the dryness of the air descending into the Antarctic anticyclone.
The measurements suggest that local topography and distance from the coast and moisture source have an effect on snow properties. In Antarctica an increase in distance from the coast also means an increase in surface elevation. Both influence snow properties. Topographic effects on the katabatic winds also appear important.
Acknowledgements
Academy of Finland finances the Seasonal Snow in Antarctica project (Academy project No. 43925 to M. Leppäranta). CARTEL provided some of the equipment, and Universite ¨ de Sherbrooke the salary of H. B. Granberg. Logistics were provided by FINNARP. We are grateful to T. Martma of the Laboratory of Isotope Palaeoclimatology, Tallinn, for the isotope analyses. We thank E. Isaksson, J.-G. Winther and an anonymous referee for their comments and suggestions. K.C. Jezek from the Byrd Polar Research Center, Colombus, OH, provided a copy of the Antarctic RADARSAT mosaic (© Canadian Space Agency 1997).