(a) Temporal variations

Figure 2 shows the variations in concentrations of Na, Mg, and K with depth (i.e. time) down to 1.6 m at the C7, RISP Base Camp, and RIC sites (see Fig. 1 for locations). At all three sites the concentrations vary markedly with depth. The average maximum-to-minimum ratios for the three sites are 7 : 1 for Na, 10 : 1 for Mg, and 9 : 1 for K; maximum-to-mean ratios average 2.3 : 1, 2.6 : 1, and 2.2 : 1 for Na, Mg, and K respectively. Except for Mg, the variability is greater at the Base Camp site than at sites nearer the ocean.

Fig. 2 Temporal variations in Na, Mg, and K concentration peaks have been correlated both on the basis of the pattern and spacing of peaks and of the mean annual snow accumulation at the three sites.

At any one site, the distinctive high-concentration peaks generally occur at the same depths for the three elements. Also, as was reported in an earlier comparison of the C7 and Base Camp profiles (Reference Warburton and LinkletterWarburton and Linkletter, 1977), the ratio of the depths of the well-defined peaks at both sites was 1.4 : 1 (C7 : BC), a figure which is in agreement with the average accumulation ratio for the sites (Reference Crary, Crary, Robinson, Bennett and BoydCrary and others, 1962). Peak number 4 at the C7 site did not have a counterpart at the Base Camp because no sample was collected at the appropriate depth. Peak number 7 at the Base Camp site did not have a C7 counterpart because it would have occurred below the maximum depth sampled at C7.

Although the correlations of concentration maxima at RIC with those at C7 and Base Camp are not so compelling as those between C7 and Base Camp, a reasonable correlation does exist. On the basis of the data of Reference Crary, Crary, Robinson, Bennett and BoydCrary and others (1962), it is expected that the accumulation at RIC will be similar to that at the RISP Base Camp and the proposed correlation of chemical features fits this assumption.

It is important to note that, although the mean values of the ionic ratios at the three sites are on the order of 10% lower than the sea-water values, the ionic ratios for the concentration peaks are generally quite close to the sea-water ratios. This fact is important in a consideration of the possible origins of these concentration maxima.

(b) Geographic variations

The geographic distribution of the mean concentrations and the concentration ratios of the Na, Mg, and K ions at 24 sites on the south-eastern portion of the Ross Ice Shelf are indicated in Figure 3. The data presented on these maps have been contoured to suggest the general pattern of variation. Data points are often widely spaced, and alternative contour schemes are possible. The data for the region south of Roosevelt Island suggests the existence of a zone marked by low concentrations and high ratios of Na : K, Na : Mg, and Mg : K.

Fig. 3a–d. The geographic variations of Na, Mg, and K concentrations and their ratios are not a simple function of distance from the sea. Although alternative contouring schemes are possible, all seem to show a feature in the region south of Roosevelt Island.

Fig. 3e and f. The geographic variations of Na: Mg and Mg: K ratios.

Whereas the pits at C7, Base Camp, and RIC were continuously sampled with depth, the other 21 shallower pits were not. It is possible that the mean concentrations determined from these two sampling procedures may not be strictly comparable. The ratio of maximum-to-minimum concentrations for the shallow pits are, on average, half the value of the ratios found in the three deeper pits, whereas maximum-to-mean concentration values average 0.7 of those of the deeper pits. In spite of these limitations, the clusters of similar values and the sequential spatial variations on the maps indicate that the two data sets can be used together to give a general view of the geographic variability. In no cases do the data from the more intensively sampled sites (C7, Base Camp, and RIC) distort the distributional patterns. The two-dimensional diagrams of concentrations and ratios are discussed below in terms of possible causes and origins.

(c) Chemical variations with precipitation type

The most common form of precipitation which occurred at C7 and RISP Base Camp during November and December 1974 was a form of diffusional ice deposition on the nylon nets which occurred in supercooled fog conditions. C7 experienced fog for 29% of the time during its two-month occupation. It has been estimated that this diffusional deposition (often in the form of hoar frost) accounts for 5–10% of the annual accumulation on the Ross Ice Shelf (Reference Linkletter and WarburtonLinkletter and Warburton, 1976). Little snowfall occurred at C7 and only two significant snowfalls were experienced at Base Camp during the observation period.

The mean values for Na, Mg, and K concentrations and their ratios in diffusional growth are listed in Table II together with the mean values for the total accumulated snow from the pits at the same sites. The relationship of the elemental concentrations in the diffusional depositions to those of the pit snows differ at the two camps. However, the cationic ratios in the diffusional-growth ice at both sites are consistently lower than the coastal water values found in the pits. Also listed in Table II are concentrations and ratios for samples collected during a snowfall at the Base Camp site. The cationic ratios in these samples of diffusionally grown snow are also significantly lower than sea-water ratios.

Table. II. Results of chemical analysis of snows from C7 and Base Camp

(a) Temporal variations

A general correlation has been suggested among the chemical records found in the C7, Base Camp, and RIC pits even though the sites are separated by hundreds of kilometers. Although Reference Clausen and DansgaardClausen and Dansgaard (1977) have suggested that the accumulation estimates of Reference Crary, Crary, Robinson, Bennett and BoydCrary and others (1962) for the southern portion of the Ross Ice Shelf are too large, there is no evidence that the relative variations from place to place are significantly different from those indicated by the earlier work. Because only the Crary and others data cover the area where the pits were located, those data were used here.

The accumulation data indicate that the original correlations, based on the patterns and relative spacings of the peaks, are reasonable in terms of the variations in mean annual accumulation among the three sites. A detailed record of the stratigraphy was made only for the C7 pit and it has not been possible to establish the exact periods of the year in which the concentration peaks occur, solely on the basis of the C7 stratigraphy. However, oxygen-isotope data from a site near our Base Camp pit (personal communication from W. Dansgaard) suggest that many of the peaks in cation concentration represent fall and early winter periods. It is clear, however, that the high concentration values are not regularly associated with specific stratigraphic features.

Possible causes of the observed concentration peaks include:

(1) Extended periods of dry fallout of marine aerosols over the Ice Shelf. The stratigraphic record does not support this possibility because high concentrations are not associated with radiation crusts, wind crusts, or other features which would be indicative of a given layer having resided at the surface for an extended period of time.

(2) Periods of storm activity. Three factors make this a possibility: (i) Increased wind velocities associated with storms would increase the proportion of the ocean surface occupied by breaking waves leading to an increased production of sea-salt nuclei (Reference Blanchard and WoodcockBlanchard and Woodcock, 1957). Reference TobaToba (1961) estimated that an increase in wind velocity from 8.7 to 12.1 m/s would increase the number of sea-water droplets of less than 50 μm diameter entering the atmosphere by a factor of 40. (ii) During periods of high-velocity winds, the chemically-enriched surface microlayer of the ocean would be broken up and mixed into the deeper water layers. Hence, droplets entering the atmosphere would contain salts of typical sea-water proportions. The ionic ratios in the higher concentration peaks are closer to marine ratios than are those in samples with lower concentrations. (iii) As the maximum water content of the atmosphere is limited by the temperature of the cold Antarctic atmosphere, storm conditions might be expected to produce a proportionally larger increase in sea-salt particles than in liquid-water content for the clouds in which the snow is forming. This could lead to higher salt concentrations in the snowfall occurring during larger storms.

(3) Seasonal (or longer-term) minima in sea-ice extent leading to the closer proximity of large areas of open water directly offshore from the Ross Ice Shelf. By shortening the spacing between the aerosol source and the sampling sites, the observed increases in ionic concentrations could readily be produced (Reference LodgeLodge, 1955; Reference Rossknecht, Rossknecht, Elliott and RamseyRossknecht and others, 1973). Recent work by Reference Gordon and TaylorGordon and Taylor (1975) has shown that the pack ice surrounding the Antarctic continent undergoes large seasonal fluctuations.

(4) A combination of (2) and (3).

The peaks appear to be the products of large-scale meteorological events occurring over the Ice Shelf, and their chemistry indicates that the aerosols which contribute to the peaks are predominantly of marine origin.

(b) Two-dimensional variations

Information into the geographic distribution of the impurities in Antarctic snow which was previously available was based on essentially linear arrays of sampling sites because the samples were collected either during traverses (e.g. Reference Boutron, Boutron, Echevin and LoriusBoutron and others, 1972) or at fixed bases. An earlier presentation of chemical data from the Ross Ice Shelf which we have made (Reference Warburton and LinkletterWarburton and Linkletter, 1977) also took variations along a line of sampling points, and discussion centered on variations with distance from the sea. Data from the present two-dimensional array of sites (Fig. 3) presents a more complex picture.

The broad, flat surface of the Ross Ice Shelf is a region where one might expect to find a rather regular variation of chemistry with distance from the sea. However, Figure 3 makes it clear that the observed distribution is not a simple function of distance from the primary aerosol source. The geographic variations of both concentrations and ratios show a distinct discontinuity to the south of Roosevelt Island. At the moment, the spacing of data points limits our ability to define the overall extent and character of this feature in other than a general way.

The presence of this discontinuity is further suggested by the results of a study into the relationship between mean annual accumulation at sites studied by Reference Clausen and DansgaardClausen and Dansgaard (1977) and the sodium content of snow collected at the same sites by the present authors (Fig. 4). Whereas the sodium content increases with accumulation between F9 and C7, along the line between H6 and E8 an inverse relationship exists. This result suggests the existence of two zones having different meteorological or accumulation characteristics.

Fig. 4 The presence of two chemistry–accumulation regimes on the eastern portion of the Ross Ice Shelf is suggested by the two distinct relationships indicated.

The physiographic and meteorological setting of the Ice Shelf has several features of interest for the present discussion. Both the narrow tongue of higher accumulation (Fig. 5b (1)) and the elongated zone of higher mean annual temperature (Fig. 5c (1)), which cut across the topographic grain of Marie Byrd Land and the polar plateau, appear to reflect the preferred tracking of storm systems across Marie Byrd Land (Fig. 6). The high accumulation zone along the inner edge of the Ice Shelf (Fig. 5b (2)) is caused by the orographic lifting of air masses as they approach the Transantarctic Mountains. This lifting leads to deeper cloud development and to higher precipitation rates and amounts. This effect, extending some distance out onto the Ice Shelf, was observed by the authors on several occasions during the 1974–75 field season. A secondary contribution to this accumulation zone comes from snow transported from the East Antarctic plateau by katabatic winds which probably also produce a slightly warmer zone (Fig. 5c (2)) through the influence of the adiabatically-warmed air which descends through the mountains from the plateau.

Fig. 5 The physiographic and meteorological setting of the Ross Ice Shelf. 5b(1) and 5c(1) are thought to reflect an important storm track with its associated increased incidence of snowfall and advected warmer marine air. The high accumulation zone on the Shelf (5b(2)) is produced by the orographic effect of the Transantarctic Mountains. Adiabatically warmed air carried to the Ice Shelf by katabatic winds is probably responsible for 5c(2). (Maps after Reference Bentley, Bentley, Cameron, Kojima and A. J.Bentley and others, 1962.)

Fig. 6 Cyclonic frequency maxima (Reference TaljaardTaljaard, 1972) illustrated here, total cloudiness, and the distributions of cyclonic and anticyclonic centers, all indicate that most storms which affect the Ross Ice Shelf initially penetrate the Shelf in the vicinity of Roosevelt Island and the Marie Byrd Land coast.

The distributions of total cloudiness (Reference van Loonvan Loon, 1972), cyclonic and anticyclonic centers, and cyclonic frequency maxima (Reference TaljaardTaljaard, 1972) during all seasons show clearly that most storms affecting the Ross Ice Shelf pass near its north-east corner in the vicinity of Roosevelt Island. The winds recorded at Ice Shelf stations and camps reflect this. Some of the storms continue across Marie Byrd Land, but many move along the west slope of Marie Byrd Land (leading, we believe, to the features shown in Figures 5b and c), either to penetrate towards the South Pole or to curve back across the interior of the Ross Ice Shelf.

Figure 7 shows the distributions of four parameters on the Ross Ice Shelf as determined by Reference Crary, Crary, Robinson, Bennett and BoydCrary and others (1962). Mean annual temperature, snow hardness, and snow density all have their lowest values in a broad zone south of Roosevelt Island. Although recent work by Reference Clausen and DansgaardClausen and Dansgaard (1977) suggests lower values and a slightly different pattern for accumulation on the southern portion of the Ice Shelf, the overall picture remains basically the same.

Fig. 7 The variations in (a) average annual accumulation (g/unit area), (b) average annual surface temperature (°C), (c) average snow hardness (kg), and (d) average snow density (Mg/m ³ × 10 ³) were measured by Reference Crary, Crary, Robinson, Bennett and BoydCrary and others (1962) . All parameters have their lowest values in the interior of the Shelf. The patterns south of Roosevelt Island may reflect the movement of storms near and over the Ross Ice Shelf.

The distributions of chemical, meteorological, and glaciological features studied so far may be summarized as follows: Along the lines from C7 to F9, and from RIC to L7 there is a general decrease in concentration of the cations studied. Although accurate accumulation data are not available for the RIC to L7 sites, there is a positive relationship (correlation coefficient r = 0.96) between accumulation and Na concentration for the C7-F9 sequence. It appears that the general decrease in both snow and chemical accumulation found in the region near to the coast does not hold in the interior of the Ice Shelf where chemical variations are more irregular. However, the positive relationship between accumulation and chemical concentration prevails in at least part of the central region.

We suggest that storm intensity is the dominating and controlling factor from the coast across the center of the Ice Shelf. Warmer, more vigorous storms will not only penetrate further across the Ice Shelf but will contain more liquid water (hence more snowfall) and will have accumulated more marine aerosols while still over open water in the Ross Sea. The positive relationship between accumulation and chemistry suggests that the aerosol content undergoes a proportionally larger increase than does liquid-water content as storm intensity increases, probably due to the limit imposed by temperature on liquid-water content. In addition, the chemical data reflect the efficiency with which the precipitation processes clean aerosols from the air and produce a more rapid decrease in chemical concentration than in snowfall, thus accentuating the deviation from a simple 1:1 relationship. Low enrichment factors for both Mg and K (relative to Na) at C7 and RIC indicate that a relatively undiluted, unfractionated marine aerosol predominates near the sea.

A different picture emerges for the southernmost portion of the Ice Shelf. Along the line from H6 to E8, snow accumulation and Na concentration (both with significant gradients) are inversely related (r = 0.98). The accumulation gradient appears to be much affected by the orographic effect of the Transantarctic Mountains. The chemical gradient is determined by the direction of storm movement through this area, the progressive cleansing of the air by precipitation, and dilution of the aerosol by the rapidly increasing snowfall near the mountains.

The ionic ratios at the southern sites are very different from the coastal ratios to the north. The greatest deviation occurs for the Na: K ratio which averages approximately 30% of the sea-water value along the E, F, and G lines of sampling sites. The Mg: K averages 45% and the Na : Mg 65% of marine ratios at these sites. Although these values may arise only from fractionation of the marine aerosol, the proportionally greater increase in K concentration required to yield such a marked change in ratio suggests a second aerosol source. Whereas Na and Mg are generally considered to be of marine origin, K can be indicative of a continental aerosol (Reference LangwayLangway, 1967). The proximity of exposed rock and glacial deposits in the Transantarctic Mountains suggests a possible local source for an aerosol which is relatively rich in K. In addition, upper tropospheric and stratospheric dust which has traveled long distances enters the Antarctic lower troposphere under subsidence conditions over the interior plateau (Reference Hogan and NelsonHogan and Nelson, 1975; Reference Hamilton, O'Kelley and CraryHamilton and O'Kelley, 1971). This aerosol, which could be carried to areas of the Ross Ice Shelf by katabatic winds, would be expected to have lower Na : K and Mg : K ratios than does sea-water.

The general coincidence of the zone of low chemical concentrations with low values for mean annual temperature, snow density, and snow hardness south of Roosevelt Island are intriguing. Although cationic concentrations are low, their ratios are near to oceanic values. The low concentrations may indicate a tendency for cyclonic disturbances to "die" in this region, as most of the aerosol removal would have already been accomplished. The high incidence of cylonic centers near this area may be attributable to this "graveyard effect" (Reference TaljaardTaljaard, 1972). The low values for Crary's measured factors may be interpreted in a similar way. The slightly lower temperature may reflect a somewhat reduced advection of marine air across this part of the Ice Shelf whereas the lower density and snow hardness suggest a less windy character in addition to the lower temperature.

(c) Chemical variations with precipitation type

One aim of the 1974–75 field season was to collect falling snow during storms in order to study the relationship between snow growth mechanisms and chemical composition. This met with only limited success because the incidence of storms was low. Nevertheless, some information which bears on this problem was gathered.

As mentioned above, the most common form of precipitation which occurred at C7 and Base Camp during the 1974–75 field season was riming in supercooled fogs. The fog condition was generally associated with relatively warm air moving across the Ice Shelf in winds of low velocity. The distinctly cellular character of the air masses was indicated by frequent temperature oscillations of up to 5°C, which occurred at rates as rapid as 0.5°C/min. The fogs are associated with the advection of maritime air across the cold snow surface when there are no storms.

The mean concentrations for Na, Mg, and K and their ratios in the rime which formed in these fog conditions are listed in Table II. Although the air masses in which the fog formed were thought to be of marine origin, the Na : K and Na : Mg ratios are significantly lower than sea-water values. They are also distinctly different from the average ratios found in the snow taken from the pits at C7 and Base Camp. A fractionated marine aerosol is suggested as the cause for the K and Mg enrichments. Enrichment factors of 2.4 for potassium and 1.2 for magnesium are in agreement with Reference KomabayasiKomabayasi (1962). The small size of the fog droplets (around 20 μm diameter) and associated low wind velocities indicate that the enrichment may occur in association with the production of small water droplets from the chemically-enriched surface micro-layer of the ocean. The coastal values for the ionic ratios in the pit samples of snow suggest that the bulk of the accumulation at these sites is from snowfall which contains larger frozen water drops or sea-salt particles introduced into the atmosphere during storm periods when the sea surface is in a more turbulent state.

The apparent importance of the large drop and sea-salt particle contributions to the chemistry of the Ross Ice Shelf, is also supported by the results of chemical analyses of predominantly diffusionally-grown snowfall collected at the Base Camp site. Although only three samples were collected, all showed marked departures from sea-water ratios (Table II).