Temporal changes in chemical concentrations

Figures 2 and 3 show the concentrations of Na, Mg, Ca, and K with depth at the seven sampling sites. There are distinct maxima and minima occurring for all four elements at each site. The maxima and minima were not associated with any particular feature of the strati-graphy such as wind crust, depth hoar, or firn, nor with any particular depth within a specific layer. Instead, they occurred in all of the different stratigraphic features and at many different depths within those features. This result agrees with the observations of Reference Langway, Langway, Klouda, Herron and CraginLangway and others (1977) in Greenland ice. In any one profile the variations in the concentrations of the four elements are generally well correlated. The average correlation coefficients amongst the elements at all sites were 0.96 for Na : Mg, 0.80 for Ca : Na, and 0.74 for K : Na.The F9 site has some low correlation coefficients for K : Na and Ca : Na, even though the order-of- magnitude variations are still evident.

Fig.2 (a)Temporal variations in concentrations of Na, Mg, Ca, and K at site RISP-BC.(b)Temporal variations in concentrations of Na, Mg, Ca, and K at site C7.(c)Temporal variations in concentrations of Na, Mg, Ca, and K at site RIC.

Chemical profile cycles

In the absence of independent dating information (e.g. β-activity), it is difficult to identify a specific chemical maximum, in real time, in a particular profile. The cyclic nature allows only for the estimation of accumulation from peak to peak. Once a specific feature is identified by year of occurrence, the remaining cycles are then able to be dated. This factor explains the change in choice of the most recent maximum for the RIC profile from that chosen earlier by Reference Warburton and LinkletterWarburton and Linkletter (1978). Although this indicates an undesirable degree of subjectivity, it has little, if any, effect on the use of this chemical method for estimating ratios of accumulation between sites, given a set of cycles for each site.

Fig.3 (a) Temporal variations in concentrations of Na, Mg, Ca, and K at site J9.(b) T emporal variations in concentrations of Na, Mg, Ca, and K at site F9.(c) Temporal variations in concentrations of Na, Mg, Ca, and K at Roosevelt I sland site.(d) Temporal variations in concentrations of Na, Mg, Ca, and K at site Q 13.

The data presented in Figures 2 and 3 show a sampling frequency of three to four data points per ion concentration cycle. At sites J9 and F9 the same profiles were sampled at a frequency of 20 data points per cycle with no change in the number of cycles observed. This result, reported elsewhere by Reference Warburton, Warburton, Molenar, Comish, Owens and YoungWarburton and others (1981), suggests that a 10 cm deep sample is close to the minimum needed for such chemical definition on the Ross Ice Shelf.

Site-to-site correlations

When comparing chemical profiles at different locations on the Ross Ice Shelf, it should be noted that two separate field seasons were involved in the sampling. Sites C7, RISP-BC, and RIC were sampled in 1974–75 and J9, F9, R1, and Q13 were sampled in 1976–77. Several independent studies by Reference Crary, Crary, Robinson, Bennett and BoydCrary and others (1962), Reference Clausen and DansgaardClausen and Dansgaard (1977), and the present authors have made estimates of accumulation at one or more of these sites and, although these estimates are generally different for any one site, the ratios of accumulation between sites tend to be relatively consistent.

Reference Warburton and LinkletterWarburton and Linkletter (1977) have reported on good correlations found in the profiles taken at C7 and RISP-BC sites during the 1974–75 field season. These correlations depended on the ratios of accumulations determined by Crary. Table I is an extension of this work.

Table I. Correlation of Profile Features at Sites Sampled In 1974–75

Blanks in the tables represent depths where no samples were taken, which usually occurred at sites of hard crusts. The maxima and minima in the profiles at RISP-BC and RIC are highly correlated, with a correlation coefficient of 0.99. Using Crary’s isopleths, the average accumulation rate at RISP-BC is approximately 145 kg m^-2 year^-1, and the accumulation rate at RIC is expected to be close to 150 kg m-² year^-1. The mean depth ratio, represented by the regression slope M in Table I is 1.05 for the chemical features in the two profiles. This supports Crary’s relative accumulation rates at the two sites and suggests that there is an identical origin (probably the same meteorological or seasonal events), producing these relatable precipitation chemical features.

Crary’s accumulation rate at C7 is 187 kg m^-2 year^-1. With similar snow densities at the three sites, this gives an accumulation ratio between C7 and RISP-BC or RIC. of a little less than 1.3. The mean depth ratios in between C7 and the other two sites (RISP-BC and RIC) are both 1.27 with 0.99 correlation coefficients, demonstrating close relationships amongst the profile features at the three sites separated by distances up to 440 km. The slopes of the regression lines (1.27) represent the ratios of accumulations between C7 and the other two sites.

More extensive sampling was done during the 1976–77 field season, particularly at sites J9 and F9. Three pits were dug at each of these sites and sampled in an identical manner. Two profiles were taken from each pit about 3 m apart horizontally. A third profile was also taken at each site from separate pits located approximately 3–4 km from those yielding the other two profiles.Table II lists the depths of the chemical-profile features at J9 and F9. The depths of the maxima and minima in chemical concentrations of Na, Mg, Ca, and K are best estimates for those layers using all three profiles available at each site and the stratigraphy of the pits. The results show that the chemical features are highly correlated (γ = 0.99) at these two sites. The regression slope (M = 1.17) represents the best-fit depth ratio for the features and therefore would represent the ratio of accumulations at the two sites.

Table II. Correlation of chemical profile features at sites J9 and F9, Ross Ice Shelf

Total β-activity measurements at J9 and F9 sites

The measurements of total β-activity and snow densities in two separate 5 m deep pits at J9 and F9 sites on the ice shelf provided an independent means of estimating the mean annual accumulation at these sites. Figures 4 and 5 give the total β-activity as functions of snow depth, and from these results the mean accumulations at these two sites have been estimated as 94 kg m^-2 year^-1 at J9 and 84 kg m^-2 year^-1 at F9, for the 12-year period 1965–76 (see Table III). Therefore, the ratio of β-activity determined accumulations at the two sites is 1.12. This is in modestly good agreement with Reference Clausen and DansgaardClausen and Dansgaard (1977) who, for these same two sites (J9 and F9), estimated the accumulations at go and 76 kg m^-2 year^-1, respectively, and a ratio of 1.18 for the period 1955–74. Hence, there is good agreement between accumulation ratios determined by total β-activity measurements and that determined from chemical profiles at these two sites.

Meteorological and seasonal variations

Further inspection of Figures 4 and 5 shows that the 220 and 190 cm snow depths at J9 and F9 correspond approximately to 1968 or 1969 at the two sites. Since these are the approximate depths to which pits were sampled at J9 and F9 for the chemical analyses in the 1976–77 austral summer, it would appear that the chemical profiles in Figure 3a and b represent 7 to 8 years of accumulation and it can be conjectured that the oscillations in chemical concentrations are annual-seasonal. However, no temperature-related characteristics (e.g.δ^l80 values) are available to determine whether this is so.

Reference Langway, Langway, Klouda, Herron and CraginLangway and others (1977) have described the seasonal variations of chemical constituents in annual layers of Greenland ice deposits. They found that the maxima in Na, Mg, Ca, K, and A1 occurred in the early spring, and the minima in the later summer and early autumn. The ratios of maximum to minimum concentrations for Na and Mg were an order of magnitude and the present results for the Ross Ice Shelf also show such ratios. Herron and Langway (Figures 4, 5 and Table III) (1979) have suggested that the sodium maxima which they observed in snow and ice cores at three sites on the Ross Ice Shelf, occurred in the winter and early spring. It is therefore of interest to discuss when the maxima and minima might have occurred at the several Ross Ice Shelf sites and also how this relates to accumulation.

Fig. 4. Total β-activity at site J9, as a function of depth of snow, indicating possible β-activity horizons.

Fig. 5. Total p-activity at site F9, as a function of depth of snow, indicating possible β-activitj horizons.

Table III. Accumulation at sites F9 and J9 on Ross Ice Shelf based on β-activity horizons and mean snow density

Earlier work at Roi Baudoin Station (Reference Bentley, Bentley, Cameron, Bull, Kojima and GowBentley and others, 1964), near the coastline of north-east Antarctica, showed from ^l8O/^l6O measurements that the average depths of accumulation during the cold and warm parts of the year were about the same. Reference GoldthwaitGoldthwait (1958) found a maximum in accumulation in the late autumn (May—June) at Byrd Station. One of the more extensive detailed investigations of annual and seasonal variations of snow accumulation in West Antarctica was carried out by Reference Vickers and RubinVickers (1966), who showed for Little America V and Byrd Station that autumn and spring were the two seasons with highest accumulation. It was also shown that the effects of well-defined weather systems arc often widespread areally, and that the meteorological record directly correlates with known stratigraphy over large areas of West Antarctica including the region of the Ross Ice Shelf covered by this present study. Using weather maps and snow-stake farms, Vickers found that most of the large storms affect wide areas of western Antarctica almost simultaneously (±2 d), and that it was possible to trace a given meteorological phenomenon laterally in the stratigraphy over horizontal distances in excess of 1000 km.

Autumn and spring in Antarctica are characterized by alternating build-up (autumn) and decline (spring) of the inland high-pressure systems. At maximum areal extent (winter), the high is able to check the poleward migration of maritime lows near the coast. However, these maritime lows do make inroads in the autumn and are coincident with times of maximum precipitation. Snow accumulation at this time of the year along the Ross Ice Front can be greatly affected by strong onshore winds from the easterly quadrant of an intensified Ross Sea low-pressure system. It is also common for successive maritime lows along the Wilkes Land coast to cross Cape Adare and strongly reinforce a persistent low in the Ross Sea. The result is often intense and prolonged autumn storms.

When these occur, a greater proportion of the sea surface is occupied by breaking waves, leading to a higher production rate of sea-salt nuclei (Reference TobaToba, 1961) and a greater mass transfer of this material into the near-surface boundary layer. The larger wave action at the sea surface will also mix any chemically enriched surface layers with deeper water. Thus marine aerosols generated during these storms would be expected to contain chemical constituents, the concentration ratios of which would be similar to those in bulk sea-water. The larger amounts of precipitation which occur should contain, therefore, an abundance of marine trace metals accompanied by the less abundant components of the global background aerosol which is probably always present. The overall concentrations of most elements in the precipitation should be higher due to the higher chemical loading of the lower atmosphere under these high shearing-stress conditions. Not only would this explain the peaks in concentrations in the chemical profiles of the snow-pack but also the good correlations between the elements in any one profile.

Since these autumn storms occur when the sea-ice extent is near its minimum (Reference Gordon and TaylorGordon and Taylor, 1975), and the open sea surface (the source of marine aerosols) is closer to the ice front than in winter and spring, it is considered that this last factor, combined with the higher frequency and intensity of storms in autumn producing precipitation over the western part of the Ross Ice Shell, leads to the production of chemical concentration maxima in the snow- pack profiles. However, significant springtime accumulation has also been documented and this must also be considered in terms of chemical fluctuations in the snow-pack.

When the shearing-stress conditions in the boundary layer are lower, the atmosphere is more stable with light winds and less precipitation. This is more frequently the case in summer on the Ross Ice Shelf. Under these conditions, the total particulate loading in the lower atmosphere is less, due to a lower contribution from the oceanic-origin aerosols. The global background aerosol represents thereby a proportionately greater component of the impurities in the atmosphere and this should be reflected in the chemical composition of any precipitation falling during these periods. The overall effect on the precipitation chemistry would be to produce elemental ratios different from those in bulk sea-water and to give lower concentrations.