1. Introduction
Following the Chernobyl accident on the 26 April 1986, it has been shown that a new well-known radioactive reference level allows snow and ice dating in the Northern Hemisphere, as the fall-out of radioactive elements has been detected in Greenland, Scandinavia, the Alps and Svalbard. In Svalbard, radioactivity was detected at Ny-Ålesund, in the vicinity of the presently studied glaciers (Reference Pourchet, Pinglot and GascardPourchet and others, 1986, Reference Pourchet, Pinglot, Reynaud and Holdsworth1988) and at Austfonna in Nordaustlandet, eastern Svalbard (Reference Vaykmyae and PunningVaykmyae and Punning, 1989). This reference level allows determination of net glacier balances in the accumulation area (Reference Pinglot and PourchetPinglot and Pourchet, 1989) as well as the amount of radioactive fall-out. In Nordaustlandet, the amount of radioactivity due to atmospheric nuclear tests conducted in 1961 and 1962, mainly by the U.S.S.R. in Novaya Zemlya (75° N, 55° E), has also been obtained (Reference Punning, Martma, Tuygu, Vaykmyae, Purshe[Pourchet] and Pinglo[Pinglot]Punning and others, 1986; Reference Vaykmyae and PunningVaykmyae and Punning, 1989).
The aim of the present work is to describe an analysis of radioactivity in shallow ice cores on Kongsvegen and Sveabreen to identify the Chernobyl layer, and thus the 3 year mean net balance in the accumulation area. Since 1986–87, the annual balance of Kongsvegen has been determined by the Norsk Polarinstitutt using direct glaciological measurements (Reference Hagen and LiestelHagen and Liestel, 1990). Thus, the net balance obtained using the Chernobyl layer can be compared and corroborated with these direct measurements. The detection of the 1962 radioactive layer (following the 1961–62 tests) in one location on Kongsvegen allows estimation of the net balance in the accumulation area of both glaciers for the period 1962–88. On Kongsvegen, topographic work done in the ablation area in 1964 and 1991 allows estimation of the net balance in the ablation area between these two dates. Thus, the balance and the equilibrium-line altitude (ELA) on both Kongvegen and Sveabreen for a period of 26 years may be estimated and compared with the 3 years’ period (1986–89).
2. Background
The glacier complex formed by Kongsvegen and Sveabreen is situated in west Spitsbergen between 78°30ʹ and 78°50ʹN ( Fig. 1). From a common summit (Kongsveg-passet, 726 m a.s.l.), the two glaciers flow in opposite directions along an axis oriented southeast–northwest. Kongsvegen calves to the north in Kongsfjord and Sveabreen to the south in Isfjord. The glaciers are of comparable size with areas of 102 and 145 km2 and lengths of 26 and 29 km, respectively. According to the wind roses from Ny-Ålesund and Longyearbyen (see location in Figure 1), published by the Norwegian Meteorological Institute (Reference StefiensenSteffensen, 1982; Reference Hanssen-Bauer, Kristensen and StefFensenHanssen-Bauer and others, 1990), the main snowfalls occur with southeast winds, along the axes of the glaciers. At the Ny-Ålesund station located 7 m a.s.l. and 25 km northwest of the front of Kongsvegen, there is an annual average of 387 positive degree-days (PDD), while at Kongsveg-passet, on a small nunatak 90 m above the glacier top (i.e. at 815 m a.s.l.), 45 PDD were recorded in 1990, a year for which the ablation was higher than the mean value.
The glaciers studied have a sub-polar thermal regime, with a temperate firn area and cold upper layers in the ablation area. Temperature profiles down to bedrock in the accumulation and ablation areas confirm the subpolar nature of Kongsvegen (paper in preparation by J. O. Hagen). Temperature measurements at every ice-core location were also made during the present work and show that, in the accumulation area of both glaciers, the temperature reaches 0°C at about 10 m depth. Along the longitudinal axis of Kongsvegen, the measured flow velocity is around 2 m year−1.
Both glaciers in this study are surge-type. The last maximum extension of Sveabreen occurred late in the last century (Reference Salvigsen, Elgersma, Hjort, Lagerlund, Liest and SvenssonSalvigsen and others, 1990); since then, its front has retreated more than 3 km. The present calving rate is not known but the topography at the glacier front indicates that, in some years, the front will be mainly on land. Kongsvegen has a common front (named Kongs-breen) with Kronebreen, which had an important surge in 1869. This surge affected the tongue of Kongsvegen which was displaced more than 1 km into the sea. The following retreat was interrupted in 1948 by a surge of Kongsvegen itself which advanced almost 1.5 km into the sea. Since then, the glacier front has retreated about 4 km and, at present, the flow of Kronebreen compresses and blocks the front of Kongsvegen which is now 300 m wide and has an annual calving rate of only 1 × 106 m3, corresponding to melting of 1 cm water equivalent over the whole glacier surface.
3. Methods
3.1 Determination of radioactive layers
The Chernobyl accident occurred on 26 April 1986 and incoming radioactivity was noted in Svalbard by
Reference Pourchet, Pinglot and GascardPourchet and others (1986). On Austfonna (Nordaustlandet), the first snowfall containing radioactive elements occurred on 4 May and was followed by precipitation events on 10, 11, 17, 18 and 25 May. Precipitation occurring on 10 and 11 May was highly contaminated. In Ny-Ålesund, the first radioactivity was recorded on 13 May in fresh snow which fell with a southern wind. Thereafter, precipitation occurred on 20 May and 3 and 4 June but was not analysed. Meteorological records at Ny-Ålesund indicate that except for 4d, the period 10 May–6 June was almost completely cloud-covered. It is therefore likely that radioactive snowfalls occurred in the Kongsvegen and Sveabreen basins during this period.
The first ice core (K in Fig. 1), to a depth of 20.65 m, was taken in 1989 at an altitude of 639 m on Kongsvegen, and nine ice cores (A, Β … I in Figure 1; Tables 1 and 2) were taken in April 1990 on Kongsvegen and Sveabreen. The ice cores were obtained in the accumulation area to depths between 7 and 12 m and one in the upper part of the ablation area to a depth of only 5 m. Each ice core was cut into sections approximately 15 cm long (almost ten samples for one accumulation year), with an average mass of 300–400 g. After density measurement, these samples were melted and filtered according to the method described by Reference Delmas and PourchetDelmas and Pourchet (1977). The radioactive active species were extracted on to ion exchange filters in the laboratory (Reference Pinglot and PourchetPinglot and Pourchet, 1979, Reference Pinglot and Pourchet1989). The total β radioactivitiy was measured on individual filters and 137Cs was detected using γ spectrometry on composited samples.
3.2 Measurement of total β radioactivity
The measurement of total β radioactivity was carried out on samples of all ice cores. This measurement includes but does not discriminate between the total β radiation emitted by natural (cosmogenic and terrestrial) and artificial isotopes (fission products from atmospheric nuclear tests, accidents in power stations, etc.). Some years after their emission, the main artificial sources of β radiation are 90Sr and 137Cs, the latter emitting also γ radiation.
The total β radioactivity profiles (see Fig. 2) do not show clearly characteristic peaks which can be absolutely attributed to the fall-out of Chernobyl elements. This is due to the fact that the natural total β radioactivity is about 10 times the artificial radioactivity. Between the surface and about 2.5 m depth at stations A, B, C, F and I, the winter snow shows a total β radioactivity level constantly higher than 200 dph kg−1. This activity is due to terrestrial and cosmogenic radio-isotopes, mostly of short half-lives, from 238U and 232Th series, as well as 40K, etc. Below this winter deposit (noted A in column 6 of Table 1), the profiles from the previously mentioned stations clearly exhibit individual peaks which may correspond to different summer layers, because it is during this period that the local outcrops are free of snow and surface dust is exposed to aeolian transport and also because the radio-isotopes may become concentrated near the ablation surface.
3.3 Measurement of the γ radioactivity
To determine the 1986 Chernobyl reference level, γ spectrometry has been carried out on all ice cores. The samples were analysed in groups because this technique of measurement is less sensitive than total β counting. The re-grouping was made around the previously described individual β peaks.
The Chernobyl evidence is based on our measurements of 137Cs and 134Cs. The spectrometry of these elements was carried out using a high-purity germanium diode of Ν type. This detector has a relative efficiency of 20%. It is made of material free of radioactivity and located at the centre of nuclear shielding in a special building, free from all parasitic radioactivities such as cosmic rays, radon emanations, γ rays from building materials, etc.
Whilst the detection of 134Cs confirms the local Chernobyl fall-out, the work has been focused on the 137Cs activity (see Table 1 and Fig. 2). From the snow surface down to a definite depth, the caesium content is zero or insignificant (below detection level, which is about 10 dph kg−1or 3 × 10−3 Bq kg−1 at 95% confidence level). Thereafter, for every ice core, the caesium level exceeds the minimum detection level. A positive identification of 137Cs indicates the presence of snow contaminated by Chernobyl even though, due to percolation, the maximum activity may be located lower down. This assessment agrees with previous work by Arnbach and others (1989).
Ice core I (726 m a.s.l. and 12 m depth), collected at Kongsvegpasset, provides the best reference data on the Chernobyl layer of May 1986 and allows the determination of total deposition of 137Cs. Even at this station, which is the highest point on the glacier, some impurities have migrated downward into deeper layers by percolation, and 137Cs is found 2–3 m below the reference level of May 1986. The total l37Cs fall-out measured is 20 Bq m −2, which is similar to fall-outs measured in Greenland (Reference Pourchet, Pinglot and GascardPourchet and others, 1986; Reference Davidson, Harrington, Stephenson, Monaghan, Pudykiewicz and SchellDavidson and others, 1987; Reference DibbDibb, 1989) ranging from 10 to 20 Bq m−2 in the northernmost part (between 77° and 81° N) and at the highest location (Summit station). These values are, however, much lower than the fall-outs measured in Alpine glaciers (Arnbach and others, 1987; Reference Haeberli, Gäggeler, Baltensperger, Jost and SchottererHaeberli and others, 1988). At all other stations, the ice cores do not penetrate deep enough and therefore we have only partial fall-out results. Ice core H at 390 m a.s.l., in the ablation area, shows a high concentration of radioactive elements at the glacier surface. At this location, the successive radioactive layers deposited since the first atmospheric tests are concentrated at the ice surface.
Ice core Κ (639 m a.s.l. and 20.65 m deep) was taken in 1989 mainly for use as a test; thus, the radioactive profile is not continuous and samples between 5.90 and 12.95 m were not analysed. Nevertheless, its γ profile shows two steps of radioactivity at 14.82 and 16.74 m; then, a further step from 18.75 to 20.65 m which reaches a 137Cs activity of 80 dph kg−1. This activity is around 8 times the activity of the samples located between 12 and 15 m, and may be attributed to the last important nuclear tests conducted in 1961 and 1962, especially by the U.S.S.R. in Novaya Zemlya (75° N, 55° E). Comparison with total β profiles obtained in Nordaustlandet (Reference Vaykmyae and PunningVaykmyae and Punning, 1989) and at Station Central in Greenland (Reference Holdsworth, Pourchet, Prantl and MeyerhofHoldsworth and others, 1984) (used here as references), suggests that the samples from 18.65 m depth correspond to the year 1962. Radioactive profiles from an ice core of 24 m collected on top of Kongsvegen in April 1992 (Reference Pinglot and PourchetPinglot and others, 1992) and from an ice core of 26.80 m depth, collected nearby at the same time, have recently confirmed this conclusion.
3.4 Kongsvegen balance from the direct glaciological method
The mass balance of Kongsvegen has also been obtained since 1986–87 by stake measurements, snow-depth sounding profiles and density measurements in pits along the glacier. There are nine stakes from the summit at 726 m a.s.l. down to 198 m (S9, S8 … S1 in Figure 1; stake altitudes in Table 2). Soundings were made every 200 m. At the end of the ablation period, density of the firn was determined in two pits, one at the summit and one around 620 m a.s.l. Net accumulation close to the equilibrium line consists only of superimposed ice.
As mentioned previously, the calving of Kongsvegen is very small (less than 2% of the ablation by melting). Nevertheless, this calving is taken into account in the results in Table 2. The mean annual balance in the 3 years 1986–89 is positive (0.11 m w.eq.; Table 3), mainly due to a higher positive value in 1987. Reference Hagen and LiestelHagen and Liestol (1990) have measured the balances of Broggerbreen, a small glacier in the vicinity of Kongsvegen, since 1967 and their result is also presented in Table 3. There is consistency in the change of the balance of both glaciers.
4. Results and Discussion
4.1 Definition of the periods
Fall-out of Chernobyl elements occurred in May 1986. Following this event, there was negligible precipitation until the beginning of the ablation period which started in June. In Ny-Ålesund, the atmospheric temperature rose by 5°C up to 1 June and only 14 mm of rain was recorded during this month. Thus, the Chernobyl horizon corresponds to the ablation surface from 1986. Nuclear tests in 1962 in Novaya Zemlya occurred between August and December. In the present work, we link this horizon to the 1962 ablation surface, even though the upper part of this horizon could be included within the snow layer from the 1962–63 winter. The introduced uncertainty is small as the calculations will be carried out using a period of 26 years.
The sampling used in the radioactivity measurements was conducted in the spring (April and May 1989 and 1990). To obtain net-balance measurements corresponding to budget years, the current winter snow depth was measured at every pit in order to determine the 1988 and 1989 ablation surfaces. The winter snow depths, which are given in Table 1 (A in column 6), are not taken into account in the balance of the following periods of 3 years (1986–89) and 26 years (1962–88). Therefore, in Table 2 and Figure 5, the periods given correspond to 3 or 26 budget years.
4.2 The 1986–89 balance
There is consistency between the net-balance results of both the direct measurements and using the Chernobyl layer as shown in Figure 3. At the two locations where sampling was made coincidentally with stake measurements (i.e. stations F and I and stake 9, station A and stake D2) both results are identical or very close.
Results from ice cores located between stakes complete the data set and demonstrate that the maximum of net accumulation extends in a zone 2.5 km long from the top of Kongvegen and 7 km long from the top of Sveabreen. The net accumulation on Sveabreen is higher than on Kongsvegen (see Fig. 3) and the ELA is around 520 m a.s.l. for Kongsvegen and 450 m a.s.l. or a little lower for Sveabreen. Stratigraphie profiles at station G on Kongsvegen (562 m a.s.l.) indicate that the total net accumulation is composed of superimposed ice, while at station C on Sveabreen (538 m a.s.l.) the accumulation comprised both firn and ice lenses down to a depth of 6.80 m. This asymmetry of the two accumulation areas has also been observed by Reference Korolev, Sin’kevich and TarusovKorolev and others (1988). The maximum of net accumulation reflects the winter-balance distribution (see Fig. 4), especially on Sveabreen. Meteorological records at Ny-Ålesund and Longyearbyen, the two closest stations, indicate that snow precipitation occurs mainly with the winter prevailing winds from the southeast sector. This may explain the high rate of snow deposition on the windward Sveabreen and its higher net balance in the accumulation area.
For the period 1986-89, the balance for Kongsvegen was slightly positive (bn = 0.11 m w.eq.) and the ELA at 520 m a.s.l. (see Fig. 3). This ELA corresponds to an accumulation-area ratio of 0.67. On Sveabreen, for the same period, an ELA of 450 m a.s.l. corresponds to an accumulation-area ratio of 0.6 but, because of the higher accumulation value on Sveabreen, the balance of this glacier for the 3 analysed years would also have been very close to the equilibrium when the calving is ignored.
4.3 The 1962–88 balance
The net balance on Kongsvegen can be estimated using the 1962 radioactive layer in the accumulation area combined with the surface-topographic survey carried out in 1991 in the ablation area. The accumulation value is for the 26 years 1962–88 and the ablation values are for the 26 years 1964–90. In the accumulation area of Kongsvegen, at station Κ (639 m a.s.l.), the 1962 level is located between 18.75 and 20.65 m depths. That corresponds, when the snow from the winter 1988–89 is not taken into account, to a minimum total accumulation of 11.28 m or a maximum of 12.93 m of water equivalent. Annual mean accumulation is then between 0.43 and 0.50 m w.eq. for the 26 years of the period 1962–88, i.e. slightly lower than the mean net accumulation for the years 1986–89 obtained from ice core A (between 0.45 and 0.52 m w.eq.) or by direct annual measurements (0.48 m w.eq.).
In the ablation area, the net-balance values can be estimated from geodetic work for the period 1964—90. Reference PillewizerPillewizer (1967) carried out a topographic survey on the tongue of Kongsvegen in 1962 and 1964. He constructed a map at a scale of 1:50 000 with a contour interval of 10 m covering the entire ablation area of the glacier. Positions and altitudes of the ten stakes (S1 … S9 and D2) located on the central axis of the glacier were surveyed in spring 1991, and the altitude of the ablation surface in 1990 was determined. In the ablation area, the net ablation corresponds to a lowering of the surface multiplied by 0.9, the mean ice density. The ice flow is slow and almost constant along the area. Reference MelvoldMelvold (1992) has measured movements between 0.72 and 0.81 cm d −1 for stakes 1–6. Owing to a fairly constant slope of 2.5% and a constant velocity, the unknown vertical flow component may be neglected. At each stake, the change in altitude of the ice surface between 1964 and 1990 has been calculated and counted as the net ablation for the 26 years. The results (see Fig. 3) are the mean annual values for the 26 years plotted versus the mean altitudes for the period 1964–90. The result is remarkably parallel to the curve obtained from direct measurement during the period 1986–89. Long-term stability of mass-balance gradient has been noted by various authors (Reference Meier and TangbomMeier and Tangborn, 1965) and has been used as the basis of a linear model (Reference LliboutryLliboutry, 1974). From the values obtained, an annual net ablation of −34.70 × 106 m3 w.eq. can be calculated for the 26 years’ period 1964–90. In the accumulation area, the total accumulation must be estimated from the single-range value in the core at point Κ (between 11.28 and 12.93 m w.eq.). From the maximum and minimum values at this point, extrapolation of the mean accumulation curve obtained by direct measurements in the years 1986–89 and plotted in Figure 3, gives an accumulation between 22.2 and 26.7 × 106 m3 w.eq. That corresponds to an approximate mean net balance of between −0.13 and −0.08 m w.eq. and an ELA around 550–560 m a.s.l.
In the accumulation area of Sveabreen for the same 26 year period, extrapolation gives a total mean net accumulation of between 31.9 and 44.8 × 106 m3 w.eq., i.e. much greater than on Kongsvegen. The ELA was around 480 m and the accumulation-area ratio only 0.52. The ablation and calving rates are not known. Hence, in spite of the fact that the net accumulation on Sveabreen is higher than on Kongsvegen, Sveabreen more than likely had a negative balance.
In Svalbard, the change in net balance from year to year is well correlated with climatic parameters and is consistent between all surveyed glaciers (Reference Hagen and LiestelHagen and Liestøl, 1990; Reference Lefauconnier and HagenLefauconnier and Hagen, 1990). The present results may be compared with the change in balance from Broggerbreen (see Table 3) which has been surveyed since 1967. During the 2 years 1987–89 for which the Kongsvegen balance has been the same as the estimated mean net balance for the 26 year period (−0.10 m w.eq.), the Broggerbreen balance was lower (although very slightly) than its mean value since 1967. We may conclude that Kongsvegen had effectively a mean net balance near −0.10 m w.eq., i.e. not far from equilibrium. The comparison also confirms, for the recent 3 year period, a more positive balance than during the longer period. Such a situation may have been caused by the slight change in climate towards a positive balance that has been detected for Broggerbreen since 1967 (Reference Lefauconnier and HagenLefauconnier and Hagen, 1990).
5. Conclusion
Information on the mass balance of the glacier complex Kongsvegen and Sveabreen has been obtained by using radioactive layers identified in shallow ice cores. Evidence of the Chernobyl (1986) and Novaya Zemlya (1961–62) events is given by the presence of 134Cs and 137Cs. It has been found that the natural total β radioactivity is about 10 times the artificial radioactivity from the Chernobyl event. The Chernobyl layer has been found in all ice cores. The Novaya Zemlya layer has been found at one location (in the deepest ice core). On the basis of these determinations, an estimate of the mean net balance in the accumulation area for the 3 year period 1986–89 on both glaciers has been made. These results are consistent with direct measurements on Kongsvegen during the same period. Moreover, the mean net accumulation for the 26 years’ period 1962–88 has also been determined and shows a consistent link with the net ablation for the 26 years’ period 1964–90 obtained by topographic work. For the 3 year period 1986–89, the Kongsvegen balance was positive (bn = 0.11 m w.eq.), while during the period 1962–64 until 1989–90 the balance was slightly negative (bn = −0.10 m w.eq., approximately). Sveabreen, for which the calving rate is not taken into account, had a balance close to zero during the period 1986–89 and a negative one during the period 1962–88.
The present work shows that a new reference horizon resulting from the Chernobyl accident (1986) has been detected on Svalbard glaciers and that the already known Novaya Zemlya 1961–62 layer has also been detected. The discovery of these reference levels enables the determination of the net accumulation on glaciers located in remote areas in the Northern Hemisphere during a single field season. These horizons can also be used to obtain the balance when complementary information is available. By drilling a deeper ice core (in Svalbard around 35 m), it will be possible to reach layers deposited prior to the first atmospheric thermonuclear test in 1953. Detection of three reference horizons will allow comparison of net-accumulation values during three different periods. This method may be used only on glaciers having an accumulation area at a significant level above the equilibrium line and limited percolation in the highest part of their basins. Extension of the work to other glaciers in Svalbard will serve the increasing interest in glacier-balance studies.
Acknowledgements
This work was funded by the E.C. under the EPOC 0035 program. The field work was possible by a grant from the French–Norwegian Foundation for Research and Technologic Development. We express also our gratitude to Professor M. Vallon for helpful discussions and Professor M. Durand from the French Embassy in Oslo for his continuing support.
The accuracy of references in the text and in this list is the responsibility of the authors, to whom queries should be addressed.