Morphology

Riiser-Larsenisen is one of many small ice shelves along the margin of Antarctica with a width between 50 and 150 km. The grounding line is situated close to the nunatak area, Vestfjella, which is almost parallel to the coast. Few peaks in this basaltic mountain range exceed 1000 ma.s.l. and some of them barely project above the ice sheet. In the vicinity of the grounding line, the ice surface begins to rise from roughly 300 ma.s.l. to 1300 ma.s.l. close to the nunatak area farther inland, Heimefrontfjella. The ice sheet between these two nunatak areas, Ritscherflya, has an undulating surface rising towards the Heimefrontfjella mountain range which has peaks reaching up to about 2700 ma.s.l. damming the upstream ice. There is about 500 m of elevation change between the upstream side of Heimefrontfjella (Amundsenisen) and the downstream side (Ritscherflya).

A small local ice dome, Högisen (900 m a.s.l.), rises about 250 m above the surrounding ice sheet to the east and around 700 m above Riiser-Larsenisen to the west. Two small ice streams, Veststraumen and Plogbreen, are situated on each side of this ice dome.

Present climate

During the austral summer of 1988–89, an automatic weather station was established at the Finnish research station Aboa situated on the nunatak Basen (400 m a.s.l.) in the Vestfjella mountains ( Fig. 2). The mean annual temperature for 1989 was approximately −16°C (data from Finnish Antarctic Expedition). Another automatic weatherstation in Sivorgfjella (Heimefrontfjella), situated at 1200 m a.s.l., shows an annual average temperature of −18.2°C for 1988 (Jonsson, unpublished data). However, the latter station is situated in a blue-ice area close to the nunataks and is therefore not necessarily representative of the larger area.

At Halley Station ( Fig. 1), 500 km southwest of the field area, the temperature has been recorded since 1956 ( Fig. 3) (data obtained directly from the British Antarctic Survey). Another nearby temperature record comes from SANAE Station ( Fig. 1), about 500 km northeast of the Vestfjella area, where records extend back to 1957 ( Fig. 3) (Reference Jones, and Limbert.Jones and Limbert, 1987). Complete annual data series are only available up to 1984 from this station.

Fig. 3. Mean annual temperatures from Halley and SANAE. Data from Halley were obtained from the British Antarctic Survey and data from SANAE from Reference Jones, and Limbert.Jones and Limbert (1987).

Katabatic winds dominate the wind pattern in most of the Antarctic continent (Reference Parish, and Bromwich,Parish and Bromwich, 1987); in this area of Dronning Maud Land they come from the east-southeast.

Accumulation

All mass-balance calculations available from western Dronning Maud Land are compiled in Table (1). The earliest scientific work in this part of Dronning Maud Land was done during the Norwegian-British-Swedish Antarctic Expedition, 1949–52. At the coastal station, Maudheim ( Fig. 1), the average accumulation was cal-culated from a combination of stake measurements and stratigraphie studies (Reference Schytt,Schytt, 1958). From a 300km traverse inland, the mass-balance values were found to be of the same order of magnitude as on the ice shelf. When the station was revisited in 1960, the average mass balance between 1952 and 1960 showed a slight increase (Reference Swithinbank,Swithinbank, 1962). Further to the east, on Fimbulisen ( Fig. 1), the mass balance was found to be somewhat higher than at Maudheim during the same time periods (Reference Lunde,Lunde, 1961). The accumulation rate at Georg von Neumayer, between 1964 and 1979, was estimated using tritium analysis (Reference Reinwarth,, Rauert,, Stichler, and Moser,Reinwarth and others, 1982) and with δ¹⁸O for 1977–81 (Reference Reinwarth,, Graf,, Stichler,, Moser, and Oerter,Reinwarth and others, 1985).

Table 1. Compilation of accumulation measurements available for western Dronning Maud Land

Accumulation studies have been carried out on Riiser-Larsenisen using both stake measurements and oxygen-isotope stratigraphy on firn cores (Reference Lunde,Lunde, 1961; Reference Repp,Repp, 1978; Reference Gjessing, and Wold.Gjessing and Wold, 1986; Reference Orheim,Orheim and others, 1986). Both stratigraphie studies (Reference Repp,Repp, 1978) and stake measurements (Reference Gjessing, and Wold.Gjessing and Wold, 1986) show higher accumulation values for the period 1975–78 than is suggested by the oxygen-isotope stratigraphy from the same area (Reference Orheim,Orheim and others, 1986).

The summer surface is generally poorly developed at Riiser-Larsenisen and, therefore, accumulation estimates from pit studies are not reliable. Melting occurs in the snow during the summer season but it is insufficient to penetrate a complete annual layer (Reference Gjessing, and Wold.Gjessing and Wold, 1986).

Before the Swedish Antarctic Expedition of 1988–89, no accumulation measurements had been made above the grounding line in the Vestfjella area.

Ice velocity

Ice-velocity measurements show that the ice velocity on Ritscherflya is about 10 m year⁻¹ (Holmlund, unpublished data). The ice velocity increases to around 30 m year⁻¹ at the grounding line and the highest velocity, 130 m year⁻¹, is found about 10 km downstream from the grounding line. Near the ice front, the velocity is about 110 m year⁻¹ (Reference Gjessing, and Wold.Gjessing and Wold, 1986).

The Heimefrontfjella mountain range dams the inland-ice flow and the ice is channelled through the mountains in smaller outlet glaciers; most of the ice is drained through Veststraumen and only a small amount through Plogbreen ( Fig. 2). Ice-velocity measurements at Plogbreen showed a velocity close to 100 m year⁻¹ (Reference Holmlund,, Isaksson and Karlén.Holmlund and others, 1989). At present, ice velocities at Veststraumen are unknown but they will be determined in the future as part of SWEDARP.

Field

Laboratory

Accumulation from stake measurements

The snow-accumulation measurements obtained from stakes along the traverses are summarized in Table (2). The spacing between the stakes is 2 km over the ice shelf and 0.5 km for the remainder of the traverse. The stakes were measured during 1988 and 1989. The total number of stakes is 529.

Table 2. Accumulation data for stake traverse over Riiser-Larsenisen and Ritscherflya. The standard deviations of the accumulation measurements are in parentheses

So far, only 1 year of accumulation measurements is available for the whole traverse ( Fig. 4, Table (2)) but, for the part of the stake traverse over Ritscherflya, the 1988 accumulation measurements are also available ( Fig. 5, Table (2)). The density was obtained from snow pits at firn-core locations A-Η ( Fig. 2). The accumulation was calculated for 1988 using the mean densities in the uppermost 25 cm of snow pits at the firn-core locations D-H.

Fig. 4. The 1989 surface accumulation along the coastinland traverse (Reference Näslund,, Pohjola and Stroeven.Näslund and others, 1991). In the area from the coast to Basen, the spacing between the stakes is 2 km and, between Basen and Heimefrontfjella, it is 0.5 km. The thick line is the running mean over 10 km. The approximate locations of the grounding line, Basen and Heimefrontfjella are indicated by arrows.

Fig. 5. Accumulation along the Basen (Vestfjella)–Heimefrontfjella stake traverse during 1988 (Reference Holmlund,, Isaksson and Karlén.Holmlund and others, 1989) and 1989 (Reference Näslund,, Pohjola and Stroeven.Näslund and others, 1991). Both curves are running means over 10km (20 stakes). The approximate locations of Basen and Heimefrontfjella are indicated by arrows. The thin line is the elevation along the stake line. The elevation measurements are based on GPS measurements at five core locations.

Dating

Before the isotopic stratigraphy can be translated into an accumulation record, the δ¹⁸O must be dated. Core Β was not analysed for oxygen isotopes and the material was retained for ¹⁰Be analysis (Reference AlDahan,, Possnert, and Isaksson,AlDahan and others, 1990). The mean δ¹⁸O, the total number of samples analysed and the position of each core are listed in Table (3).

Table 3. Positions of firn cores

The isotopic stratigraphies in the cores from Riiser-Larsenisen ( Fig. 6a–b) show well-pronounced seasonal variation. Differences of 10% between summer and winter surfaces are common. Also, the seasonal strati-graphies in cores from between the grounding line and Heimefrontfjella ( Fig. 6c–g) are sufficiently clear to allow recognition of annual accumulation. This is not the case with the core from Amundsenisen ( Fig. 6h), which shows a more ambiguous isotope stratigraphy.

Fig. 6.a and b. The δ¹⁸O stratigraphy and the adapted time-scales for cores A and C from Riiser-Larsenisen. c and d. The δ¹⁸O stratigraphy and the adapted time-scales for cores D and Ε from Ritscherflya. e and f. The δ¹⁸O stratigraphy and the adapted time-scales for cores F and G from Ritscherflya. g. The δ¹⁸O stratigraphy and the adapted time-scales for core Η from Ritscherya.

We believe the stratigraphies could be established because of a distinct annual variation in δ¹⁸Ο. Comparing patterns in δ¹⁸O variations between localities yielded further support for this conclusion. A time-scale was assigned to each core by comparing the seasonal δ¹⁸O variations in cores A, C-H, seeking similar patterns. To make this approach possible, it was assumed that no annual accumulation layers were missing at Riiser-Larsenisen (cores A and C), where the accumulation was high. These cores were used to identify annual layers in the cores with low accumulation farther inland. Each of the δ¹⁸O versus depth relationships was then compared with the δ¹⁸O record in precipitation from Halley (International Atomic Energy Agency, 1975, 1979, 1984, 1990). Similar patterns and particularly marked peaks in the δ¹⁸Ο stratigraphies were used as stratigraphie markers. However, a detailed correlation could not be performed because the distribution of precipitation during the year is known in the Halley δ¹⁸Ο record but not in the firn-core records. Another problem is of course the geographical distance between the sites of the records.

The summer surface (the most positive δ¹⁸O) is used as the annual stratigraphie marker. In this way, more than 15 years can be identified. The adapted time-scales for cores A, C, D, E, F, G and H are presented in Figure 6a-g. Because the summer surface of 1988–89 in core C was not well developed at the time of sampling, the accumulation for 1988 could not be calculated for this particular core.

As already mentioned, the oxygen-isotope stratigraphy for core J is more complicated and the same dating technique was therefore not possible. Nevertheless, because an additional independent parameter for the construction of the time-scale β activity) was measured in core J, this core could be used for accumulation calculations. Despite the alternative dating method for core J, the oxygen-isotope stratigraphy is still difficult to interpret.

β activity

The β-activity profile for core J is shown together with the oxygen-isotope profile in Figure 9. The stratigraphy suggests that the firn in the lower part of the core was deposited prior to thermonuclear testing. The traditional interpretation for Antarctic snow is that the first increase above background is the 1954–55 surface. Therefore, in this core, this surface is at a depth of 8.8 m. The next peak at 6.5 m depth should then be the 1964–65 surface. With this interpretation, the 1970–71 peak is not present in the stratigraphy. The other possible interpretation could be that the 6.5 m peak is the 1970–71 surface and the previous peak is the one for 1964–65. However, due to the extremely low activity in the lower part of the core, this interpretation is not favoured (personal communication from Dr Ε. Mosley-Thompson, 1990).

Fig. 9. δ¹³O record and the β-activity profile for core J from Amundsenisen.

The less-pronounced β-activity peak for 1954–55 in this area, compared to records from interior Antarctica (e.g. Reference Petit,, Jouzel,, Pourchet, and Merlivat,Petit and others, 1982), is one that has also been recognized by others; coastal stations and stations in the Antarctic Peninsula generally have a weaker 1954–55 level than do the inland stations (Reference Aristarain,, Jouzel, and Pourchet,Aristarain and others, 1986).

Based on the β-activity horizons, the accumulation can be calculated for the time periods 1955–65, 1965–88 and for the whole interval 1955–88 (Table (5)).

Spatial variations in surface accumulation

Stake measurements show a large variability in accumulation over short distances ( Fig. 4). The 1988 accumulation measurements from Ritscherflya show a standard deviation of 70%. Some of the variations are most likely an effect of differences in the slope of the longwave dunes, visible on satellite images, whilst others are due to sastrugi. The large spatial variability invokes the use of smoothing to reveal the overall pattern. The smoothed record of stake measurements shows that the accumulation decreases inland, at least up to about 300 km from the coast. This is expected, since precipitation and accumulation are functions of temperature, elevation and distance from the moisture source (Reference Muszynski, and Birchfield,Muszynski and Birchfleld, 1985; Reference Giovinetto,, Waters and Bentley,Giovinetto and others, 1990). Superimposed on this overall pattern are other small differences in surface accumulation. A slight decrease in accumulation is evident in the grounding-line area on Riiser-Larsenisen. This change in accumulation is in accord with previous work in the same area (Reference Gjessing, and Wold.Gjessing and Wold, 1986) as well as on the Brunt Ice Shelf (Reference Thomas,Thomas, 1973). A likely explanation is the steeper surface slope in the area of the grounding line (Reference Thomas,Thomas, 1973). Stakes closer than about 20 km from the coastline show a lower accumulation rate than stakes farther inland on the ice shelf. A slight decrease of snow accumulation in a 4–5 km wide area on the outer edge of the ice shelf has also been observed on the Brunt Ice Shelf (Reference Thomas,Thomas, 1973) and on the ice shelf seaward of Maudheim (Reference Swithinbank,Swithinbank 1957). This is most likely due to increased wind scouring in the zone closest to the coast. An accumulation minimum also occurs around 250 km from the coast, in an area without any major differences in either elevation or slope. It is possible that this minimum is caused by increasing wind scouring due to wind channelling in the vicinity of the Heimefrontfjella mountain range. However, a similar phenomenon has been observed along a traverse inland from Mirny, where there are no nunataks (Reference Young,, Pourchet,, Kotlyakov,, Korolev, and Dyugerov,Young and others, 1982). Because the Antarctic surface-wind patterns are still relatively unknown (Reference Parish,Parish, 1988), we leave this subject without further speculation. Over the final 50 km of the stake traverse, just before Heimefrontfjella, the accumulation again shows a slight increase. At this point, it is difficult to say whether this is an effect of the mountain range or whether it is part of the larger-scale distribution of surface accumulation.

Despite the fact that the accumulation rate for 1989 is more than 100% higher than for 1988, the spatial distribution is maintained with a very high degree of coherence ( Fig. 5). Similar results about the coherence in the spatial pattern were obtained by Reference Young,, Pourchet,, Kotlyakov,, Korolev, and Dyugerov,Young and others (1982) for stake traverses in the Vostok and Dome C areas.

Some of the stakes show a negative accumulation; 3.8% of the stakes show a negative accumulation value for the 1988 accumulation year and 0.3% for 1989. The negative accumulation value is only a few centimetres for most of these stakes (the largest negative value is −7 cm for one stake during 1988). Interestingly, during our field work in the area in 1988–89, we were able to follow the vehicle tracks from the previous year over long distances. There are several possible explanations for the low accumulation: measurement error, snow compaction, sublimation or wind-scouring. Because most of the stakes with negative accumulation are in the low-accumulation area around 200 km from the coast, wind-scouring seems to be the most likely explanation.

Temporal variations in net accumulation

2 years’ stake measurements show that, in addition to a high spatial variability, there is also a large temporal variability ( Fig. 5). Furthermore, the net-balance records from the oxygen-isotope stratigraphy show a considerable inter-annual variability — up to several hundred per cent (Fig. 7a–g). Therefore, it is obvious that several years of accumulation measurements are necessary to produce a reliable estimate of the net accumulation; shorter periods are far too influenced by annual variations in precipitation and spatial variations. It has been suggested that a period of 10 years is sufficient when using an accumulation record from one site for regional purposes (Reference Morgan,Morgan, 1985; Reference Mosley-Thompson,, Kruss,, Thompson,, Pourchet and Grootes.Mosley-Thompson and others, 1985).

Table 5. Mean annual accumulation data for firn core J on Amundsenisen based on the β-activity stratigraphy

The temporal variability in accumulation shows a common pattern for many of the cores. All of the cores from the ice shelf and Ritscherflya show a decreasing accumulation trend during the period of 1976–89 ( Fig. 7a–g). Linear-regression analysis on these accumulation records suggests a 1.4–2.1 cm w.e. annual decrease during this period. What caused this trend? Because it has previously been found that the precipitation rate over Antarctica is strongly correlated with temperature, it is interesting to compare the obtained accumulation record to the Halley temperature record. The Halley temperature record is preferred to the SANAE record, because it is longer. Indeed, a temperature decrease of about 1°C has been recorded at Halley during the time covered by the accumulation record ( Fig. 3). Considering the distance between Halley and western Dronning Maud Land, the temperature and the accumulation records show surprisingly similar trends ( Fig. 10). However, the inter-annual correlation is not striking, but the overall patterns, which probably reflect the climatic signal filtered from any local weather patterns.

Fig. 10. Mean annual accumulation, 1976–89, obtained from firn cores and lyear of stake measurements (1989), and mean annual temperature at Halley for the same period.

The net accumulation at Riiser-Larsenisen of 39.0 cm w.e. (Table (3)), obtained from two firn cores covering the 1976–88 period, is in agreement with results from Reference Orheim,Orheim and others (1986), although the data are for 1957–78. Assuming that these two data sets are of equal quality, they can be combined to a single data set covering the 1957–88 period. Only one year of measurements, 1978, overlaps and the means from both are used in the compilation. Hence, the total mean accumulation for this combined period is 34.7 cm w.e. This 31 year long accumulation record suggests an increase in the late 1970s and a decrease after ( Fig. 11). The temperature record from Halley during the same time does suggest that these changes can be related to climatic changes. Looking at the graph with the 3 year running mean of the Halley temperature record and the Riiser-Larsenisen accumul-ation record ( Fig. 11), it is striking that the positive accumulation anomaly, starting around 1975, cor-responds quite well to a warm period at Halley. The 1973–75 temperature increase of about 2°C at Halley is contemporaneous with a 50% increase in accumulation at Riiser-Larsenisen which is somewhat higher than a precipitation increase of 520% K⁻¹ given in a compil-ation by Reference Robin,Robin (1977). It is very likely that this accumulation increase was caused by other factors, such as changes in the storm tracks, less wind-scouring, etc. Unfortunately, there is a lack of high-resolution accumulation records from other parts of Antarctica which could confirm these changes. However, increased accumulation rates have been presented by Reference Morgan,, Goodwin,, Etheridge, and Wookey,Morgan and others (1991) from Wilkes Land.

Fig. 11. Accumulation record from Riiser-Larsenisen, 1958–87, compared with the mean annual temperature record from Halley, 1957–89. Both records are 3 year running means.

The accumulation changes farther inland on Amundsenisen are based on a single core J, and the β-activity measurements do not ( Fig. 9) suggest any large changes in surface accumulation since 1955 (Table (5)). Using the 1954–55 and 1964–65 β-activity surfaces at Dome C, Reference Petit,, Jouzel,, Pourchet, and Merlivat,Petit and others (1982) found 30% higher accumulation for the period 1965–79 compared to 1955–65, and similarly at the South Pole (Reference Jouzel,, Merlivat,, Petit, and Lorius.Jouzel and others, 1983). If this change in accumulation is detectable in the interior parts of Antarctica, where the accumulation is less than in the relatively coastal area of Dronning Maud Land, such a change should also be readily found in our record. Because of indications of decoupling of the climate between different parts of Antarctica (e.g. Reference Raper,, Mayes,, Jones, and Salinger,Raper and others, 1984), there is a possibility that changes in snow accumulation are also different. Another possibility is that, because the core from our field area spans an additional decade, 1980, the decreasing accumulation trend that we can see in the firn-core record from Riiser-Larsenisen and Ritscherflya can negate the accumulation increase that occurred during 1970. Finally, one has to emphasize that our data are only based on this single core with all the uncertainties that come with it.

The lack of high-resolution accumulation records covering the same time period as this work makes it difficult to say whether the temporal changes in accumulation apparent in this part of Dronning Maud Land are local or occurred over larger areas of the Antarctic continent; as mentioned, similar results have recently been presented from Wilkes Land (Reference Morgan,, Goodwin,, Etheridge, and Wookey,Morgan and others, 1991). This has implications when calculating the mass balance for Antarctica. In the latest mass-balance compilation by Reference Bentley,, Giovinetto,, Weiler,, Wilson, and Severin,Bentley and Giovinetto (1990), they concluded that a positive mass balance exists for the Antarctic ice sheet, equivalent to 0.2–1.1 mm year⁻¹ of sea-level lowering. However, the area where SWEDARP is active is a part of one of the drainage systems (called KK’), where they suggest a negative mass balance. The reason for this is that the melt rates beneath the ice shelf have been found to be higher than that required to maintain a steady-state condition (Reference Thomas,Thomas, 1973; Reference Gjessing, and Wold.Gjessing and Wold, 1986). Reference Bentley,, Giovinetto,, Weiler,, Wilson, and Severin,Bentley and Giovinetto (1991) further used the positive mass balance in a nearby drainage system in Dronning Maud Land (called AA’) as an example of the accuracy of their mass-balance estimates. This drainage system lacks any major ice streams or other outflow systems and it has mountain ranges which dam the interior ice flow; a positive mass balance is therefore easy to visualize. The total mass balance of this drainage area is currently being worked out and will be presented by Holmlund and others. However, as long as large parts of Antarctica lack field data, such as the now-mentioned areas, we can only speculate about the total mass balance.