Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-12-01T09:18:46.172Z Has data issue: false hasContentIssue false

Holocene electrical and chemical measurements from the EPICA–Dome C ice core

Published online by Cambridge University Press:  14 September 2017

R. Udisti
Affiliation:
Department of Chemistry, University of Calabria, 1-87030 Arcavacata di Rende (Cosenza), Italy Department of Public Health and Environmental Analytical Chemistry, University of Florence, 1-50121 Florence, Italy
S. Becagli
Affiliation:
Department of Public Health and Environmental Analytical Chemistry, University of Florence, 1-50121 Florence, Italy
E. Castellano
Affiliation:
Department of Public Health and Environmental Analytical Chemistry, University of Florence, 1-50121 Florence, Italy
R. Mulvaney
Affiliation:
British Antarctic Survey, Natural Environment Research Council, High Cross, Cambridge CBS OET, England
J. Schwander
Affiliation:
Physics Institute, University of Bern, CH-3012 Bern, Switzerland
S. Torcini
Affiliation:
Ente Nazionale Energia e Ambiente, AMB, CRE Casaccia, 1-00100 Rome, Italy
E. Wolff
Affiliation:
British Antarctic Survey, Natural Environment Research Council, High Cross, Cambridge CBS OET, England
Rights & Permissions [Opens in a new window]

Abstract

The comparison between electric (electric-conductivity measurement (ECM) and dielectric profiling (DEP)) and chemical sulphate and chloride) depth profiles along the first 400 m of the EPICA-Dome C ice core revealed a very good fit, especially for peaks related to volcanic emissions. From the comparison between these profiles, a dominant contribution of sulphuric acid to the ionic balance of Antarctic ice for the Holocene was confirmed. A progressive increase with depth was observed for chloride concentrations, showing a change of relative contribution between sulphate and chloride. A higher increase of chloride was evident between 270 and 360 m depth, probably due to a change in source or transport processes or to an increase of the annual snow-accumulation rate. The DEP, ECM and sulphate ice signatures of Tambora (AD 1816) and El Chichon (?) (AD 1259) eruptions are described in detail. A characteristic peak series, due to HCl deposition, was identified at 103–109 m depth from the ECM, DEP and chloride profiles.

Type
Research Article
Copyright
Copyright © The Author(s) 2000

1. Introduction

In recent years, ice-core operations have been revolutionized by the ability to make many measurements in the field. This enables scientists to detect events and examine background trends very rapidly and to adjust their sampling in the field accordingly. Electric-profiling methods have become well-established (Reference Hammer, Clausen and DansgaardHammer and others, 1980; Reference Wolff, Moore, Clausen, Hammer, Kipfstuhl and FuhrerWolff and others, 1995).

Electric-conductivity measurements (ECM) and dielectric profiling (DEP) are fast, inexpensive, non-destructive techniques, performed in situ directly on the solid ice, able to give useful, but non-specific, information about the ionic content of the ice. In fact, the ECM (Reference Hammer, Clausen and DansgaardHammer and others, 1980) and a large part of the DEP signal are related to the electrical mobility of H+, but they do not distinguish between the different anions associated with the H+ ion. In addition, other conductive species (chloride and ammonium), also present in the ice as salts, give significant DEP signals (Reference Moore, Wolff, Clausen and HammerMoore and others, 1992,Reference Moore, Wolff, Clausen, Hammer, Legrand and Fuhrer1994; Reference Wolff, Miners, Moore and ParenWolff and others, 1997). For this reason, the ability to carry out some chemical analyses in the field constitutes a complementary method. Continuous chemical analysis (continuous flow analysis (CFA)) applied to ice-core processing is a more recent innovation (Reference Fuhrer, Neftel, Anklin and MaggiFuhrer and others, 1993) and the number of chemical species that can be analysed rapidly in the field has been growing.

Recently, a semi-continuous method, based on flow-analysis lon-chromatographic-hyphenated techniques, has been set up for the fast, in situ, determination of chloride, nitrate and sulphate (Udisti and others, in preparation). This method was applied for analysis of the ice core drilled at Dome Concordia (Dome C: 75°06′06"S, 123°23′42"E; 3233 m a.s.L), within the European Project for Ice Coring in Antarctica (EPICA).

The site is expected to yield a climate record of the last 500 000 years. In the shallower parts of the core, the unprecedented range of measurements and their depth resolution will lead to new understanding of climate and biogeochemical variability on short (annual and greater) time-scales. During the 1997/98 and 1998/99 Dome C campaigns, the drilling reached a depth of about 780 m, of which about 600 m has undergone processing, including several analyses in the field. In this paper, we compare results from the top 400 m of ice from electrical measurements (mainly giving an indication of acidity), and chemical measurements (with an emphasis on sulphate). The 400 m depth was chosen as being near the limit between the Holocene and the Last Glacial period, based on earlier data, including that from the "old" Dome C (74°39′ S, 124° 10′ E; 3240 m a.s.L) ice core drilled during the 1977/78 field season (Reference Lorius, Merlivat, Jouzel and PourchetLorius and others, 1979); about 65 km north of the new one.

For Holocene ice in central Antarctica, by far the largest component of the ionic budget of ice is made up of acids and sulphate (Reference Legrand and DelmasLegrand and Delmas, 1988; Reference Legrand, Leopold, Domine, Wolff and BalesLegrand and others, 1996), for the cations and anions respectively, with much smaller components from sea-salt cations, from nitrate and chloride and other ions. High-resolution continuous records of sulphate and acidity are therefore of particular interest. Apart from the background trends over thousands of years, sporadic events, lasting only one or a few years, are of great interest for a number of studies. Where they result from volcanic eruptions, events normally (though not exclusively) consist largely of sulphuric acid. Previously, such events have been identified from continuous electrical measurements for acidity (e.g. Reference ClausenClausen and others, 1997) or from sulphate analyses (Reference Zielinski, Mayewski, Meeker, Whitlow and TwicklerZielinski and others, 1996), although rarely have both been compared at high resolution.

The aim of this paper is to compare the electrical measurements (ECM and DEP) with the concentration-depth profiles of sulphate and chloride, which make a significant contribution to snow acidity and which constitute, together with nitrate, the most plentiful anions in the ionic budget in Dome C ice (Reference Legrand and DelmasLegrand and Delmas, 1988). In particular, some in-phase peaks of ECM, DEP and sulphate were observed in detail to obtain information about some volcanic emissions in the Holocene period. On the other hand, particular ECM and DEP peaks were not related to sulphate content and can be explained by the presence of other snow components, especially chloride. The identification of the chemical species contributing to the increase of the ionic content will make it possible to evaluate the temporal change of different source contributions to the atmospheric aerosol.

2. Sampling and Methods

2.1. Sampling station

As part of the EPICA project, Dome C was chosen for an ice core > 3000 m long, able to provide paleo-environmental information on the last 500 000 years. The exact location of the drilling site, on top of the topographic dome, was established by geodetic, topographic and radar surveys (Reference Tabacco, Passerini, Corbelli and GormanTabacco and others, 1998). Some details of the site and the first year of drilling have been presented previously (Reference Wolff, Basile, Petit and SchwanderWolff and others, 1999).

2.2. Ice-core treatment

At Dome C cores were cut into lengths of 2.2 m and passed to a purpose-built insulated laboratory (made of cold-room sections) adjacent to the drilling tent. Most of this laboratory was maintained at a temperature of–19°C; despite the low ambient air temperatures (generally below –30°C), the room tended to warm so it was necessary to ventilate it with cold air taken from a trench below the snow surface. A separate room for chemical analyses was maintained close to 18°C by heating.

Cores were allowed to equilibrate to the laboratory temperature and then passed through a processing line that included: two electrical measurements (DEP and ECM); sectioning of ice for analyses to be made in Europe; chemical measurements by CFA; and semi-continuous ion-chromatographic (IC) analysis.

2.3. DEP measurements

The DEP method used at Dome C is described in detail elsewhere (Reference Wolff, Basile, Petit and SchwanderWolff and others, 1999). Measurements of capacitance and conductivity were made on the whole (uncut) core; the value used here is the 100 kHz conductivity, which is very close (1–2%) to the high-frequency limit of the conductivity (.Too), which has been presented in earlier papers. Measurements were made every 20 mm, and have been corrected to –15°C using an activation energy of 48 kJ mol−1 (0.50 eV) for the pure ice part of the conductivity, and 21 kJ mol−1 for the part controlled by chemical content (Reference Wolff, Moore, Clausen, Hammer, Kipfstuhl and FuhrerWolff and others, 1995). Sections containing core breaks have, in general, not been removed from the DEP record presented, but are normally recognized easily as dips in the value of σ below 9μSm–1 (the expected value for pure ice after densification, shallower firn having lower background values).

DEP conductivity responds to acidity, ammonium, and chloride (Reference Moore, Wolff, Clausen and HammerMoore and others, 1992, Reference Moore, Wolff, Clausen, Hammer, Legrand and Fuhrer1994; Reference Wolff, Miners, Moore and ParenWolff and others, 1997), and the electrode system used at Dome C was previously calibrated for Greenland ice. Based on the chemical concentrations measured on the previous Dome C core drilled in the late 1970s (Reference Legrand and DelmasLegrand and Delmas, 1988), we would expect the signal in Holocene ice to be dominated by the acidity, and therefore to be very similar to the ECM signal (Reference Wolff, Basile, Petit and SchwanderWolff and others, 1999).

2.4. ECM measurements

Electric-conductivity measurement (ECM) is mainly a measure of DC conductivity, traditionally carried out by dragging a pair of electrodes with a high voltage between them along a core and measuring the current between the electrodes (Reference Hammer, Clausen and DansgaardHammer and others, 1980; Reference Neftel, Beer, Oeschger, Zurcher and FinkelNeftel and others, 1985). At Dome C a new system, developed at the University of Bern, was used. The system will be described in detail elsewhere and has been summarized by Reference Wolff, Basile, Petit and SchwanderWolff and others (1999). An assembly of seven electrodes (8 mm apart), made of a carbon-doped silicon rubber, was lowered onto a flat surface of the ice core and 350 V were applied across each adjacent pair of electrodes in turn. The current between them was sampled at regular intervals after a settling time and averaged. The electrodes were lifted and moved 1 mm along the core and the measurement repeated. The data presented here are given as conductances averaged to 10 mm and corrected to –15°C, using an activation energy of 22 kJ mol−1 (0.23 eV).

2.5. Semi-continuous IG measurements

The determinations of chloride, nitrate and sulphate have been carried out by a semi-continuous method achieved by coupling ion-chromatographic separation with a flow-analysis method for direct and continuous sample injection (Udisti and others, in preparation). The sample was produced by a continuous melter (Reference Sigg, Fuhrer, Anklin, Staffelbach and ZurmuhleSigg and others, 1994) able to decontaminate a 1.1m ice-core segment (about 32 × 34 mm section) with a constant speed (typically, 40 mm min−1), during the melting. The IC system allows one determination every minute, therefore the typical resolution was one measurement every 40 mm of ice. The method detection limits are below 0.5 μgL−1 for all species by using a pre-concentrator loaded with 0.75 mL of sample. The reproducibility was better than 2% for sulphate and nitrate, and better than 4% for chloride, in the range 5–50 μg L−1. The method was initially designed for the determination of sulphate only, so that chloride and nitrate measurements carried out in the first Dome C campaign (1997/98) can only be used as approximate values, especially for concentrations below 20 jig L−1 (chloride) and 5 μg–1 (nitrate), because of the closeness of their chromatographic peaks to the baseline water dip. An optimization of the working conditions permitted a better separation among the three analysed components and, especially, a sufficient time between the retention time of chloride peak and the one of the water dip. Figure 1 shows a typical chromatogram carried out on a section of the Dome C ice core. The scale expansion shows the complete separation of the three components and the ability to determine the chloride peak out of the water dip. Sulphate and nitrate can be measured without interference from other components (such as bromide and phosphate) that may be present in the sample. In addition, bromide and phosphate are likely not present at significant levels in Antarctic ice cores, given the quasi-perfect ionic balance between anions and cations observed by Reference LegrandLegrand (1987) in Dome C snow. Carboxylic acids (especially acetate and formate) and methanesulphonic acid (MSA) peaks may be partially superimposed on the chloride peak. By considering the higher detector response (conductometric detector with conductivity suppressor) to chloride concentration, with respect to that obtained for organic acids at the same concentration, an error φ10% is estimated for the determination of chloride when its concentration is > 10 μ IT1 and the cumulative concentration of organic acids is φ20μgL−1. In fact, at Dome C, the expected levels of carboxylates are close to 1 μgL–1 or less (Reference Legrand and SaigneLegrand and Saigne, 1988) and the levels of MSA are close to 5 μg L–1 during the Holocene (Reference Saigne and LegrandSaigne and Legrand, 1987).

Fig. 1. Semi-continuous (1 measurement every minute) ion chromatogram of a section of EPICA-Dome C ice core. Expanded figure shows separation between chloride (1), nitrate (2) and sulphate (3) peaks.

3. Results and Discussion

3.1. Data discussion

From a general point of view, there is a very close relationship among the different parameters in the whole 0–400 m depth interval, especially for events characterized by a fast increase of the signals with respect to the background level, such as the volcanic inputs. The 400 m depth was set as an approximate limit between the Holocene and the interglacial-glacial transition.

As an example of the common trend, Figure 2 shows the profiles of ECM (a), DEP (b) and sulphate (c) in the 100–200 m depth range. The three profiles fit very well, with peaks in-phase between them. In particular, we can point out the close correlation between DEP and sulphate profiles, where almost all spikes coincide and often exhibit the same shape and relative height. This is particularly true for the series of peaks around 130–135, 140–145 and 153–165 m and for the peak at about 170 m. The depth with the three highest sulphate and DEP peaks (at about 131, 145 and 170 m), does not have similar ECM signals. On the other hand, at about 180 m depth, where the ECM profile shows the highest peak, the DEP and sulphate profiles show rather lower spikes. The different pattern may be due to the different efficiency of HCl with respect to sulphuric acid on the ECM response (Reference Legrand, Petit and KorotkevichLegrand and others, 1987). The IC analysis of discontinuous samples collected in these depth intervals will clarify the different pattern of the ECM profile by determining the acidic and non-acidic species content.

Fig. 2. Depth profiles of (a) ECM, (bDEP and (c) sulphate determinations in Dome Cue core at 100–200 m depth.

In spite of some particular exceptions, the similarity between ECM (more selective towards the H+ + content) and DEP (whose signals are related also to other conductive species) profiles confirms the dominance of acidity in the ionic balance of the Holocene ice (Reference Wolff, Basile, Petit and SchwanderWolff and others, 1999). A similar pattern was shown by the ECM and DEP profiles of the Greenland Icecore Project (GRIP) ice core (Reference Wolff, Moore, Clausen, Hammer, Kipfstuhl and FuhrerWolff and others, 1995) in the Holocene period (0–1623 m, 0–11550 years), where most of the volcanic signals occurred. In some GRIP Holocene sections, an in-phase periodicity of the ECM and DEP peaks seems to indicate annual cycles in acidity, probably due to the seasonal pattern of nitrate, the main acidic species at Summit, Greenland (Reference Wolff, Moore, Clausen, Hammer, Kipfstuhl and FuhrerWolff and others, 1995, and references therein). For the Dome C ice core, a seasonality of the ECM and DEP profiles is not seen because of the too-low annual accumulation rate. In addition, the acidity at Dome C is dominated by sulphuric acid rather than nitric acid, as demonstrated by the ratio 4.2 (eq/eq) between H2S04 and HN03, found by Reference Legrand and DelmasLegrand and Delmas (1988) in the Holocene period. The good correlation between the conductivity properties and the sulphate-concentration-depth profile at Dome C confirms that the Antarctic Holocene firn and ice is strongly dominated by inputs of sulphuric acid. This is especially true for the most obvious peaks, usually related to volcanic inputs.

Considering the background values, the mean sulphate concentration does not change significantly from the surface (0–100 m; 106.0 ± 43.5 μg L–1 n = 1611) to the ice-core bottom (300–400 m; 98.50 ±35.9 μgL–1 n = 2648). So, the all-Holocene mean value is very similar (95.4 ± 34.5 μg L–1 n = 9690), with a relatively low standard deviation, confirming the homogeneity of the background level. This value is a little higher than the mean value reported by Reference Legrand and DelmasLegrand and Delmas (1988) in the 1970s Dome C ice core (about 76 μgL–1 T 1 in the Holocene period), but this difference may be due to the different resolution: in this paper we report a continuous sulphate record (9690 samples with a resolution of 40 mm for approximately 1.3 years), while Legrand and Delmas analysed 55 sections, selected along the ice core, each of them covering approximately 5 years. Part of the sulphate background difference may also be due to a different accumulation rate between the new and the old Dome C drilling sites. In fact, for the new site, Reference Wolff, Basile, Petit and SchwanderWolff and others (1999) evaluated an accumulation rate about 10% less than the old one.

The chloride concentration, on the contrary, shows a progressive increase with depth. The chloride mean concentration of the last 100 m range (300–400 m; 23.3 ±14.7 μgL–1; n = 2517) is about 1.8 times higher than in the first interval (0–100 m; 12.6 ± 10.4 fig L–1 n= 1587). Therefore, there appears to be a progressive increase of the chloride contribution to the ionic balance with increasing depth in the Holocene period. Superimposed on this general trend, there is a faster increase of chloride starting at around 270 m depth (Fig. 3). The chloride concentration values remain higher than the background up to around 360 m. In this interval, the chloride profile shows concentration peaks 4–5 times higher than the background local value (around 13 μg L−1). A similar pattern of the chloride concentration in the same depth range was observed by Reference Legrand and DelmasLegrand and Delmas (1988) in the 1970s Dome C ice core, where the mean concentration value for 215–360 m (33.3 μg L−1) was about 2 times higher than the mean value in the 0–215 m interval (14.9 μg L−1). These values are in good agreement with our mean Cl- concentrations (13.5 ± 12.0 fig L−1 from 0–200 m and 27.9 ± 16.1 μg L−1 in the 270—360 m range) confirming that even the CI- measurement performed in the 1997–98 Dome C campaign are reliable, in spite of the poor separation between the chromatographic peaks of CI and of some organic acids (see section 2). The general trend of chloride in this section corresponds to the trend in background of the electrical records.

Fig. 3. Depth-concentration profile of chloride in Dome Cue core at 200–400 m depth.

The interpretation of this behaviour is very difficult in the absence of other chemical or isotopic markers, so we can give only some preliminary guess as to the cause of the higher chloride values:

  1. (1) a real increase of the chloride deposition as HCl and/or NaCl;

  2. (2) a changed HCl/NaCl ratio in the atmospheric aerosol. The NaCl species is better retained than HCl (Reference Legrand, Leopold, Domine, Wolff and BalesLegrand and others, 1996) in the snow layers; and

  3. (3) a lower re-emission into the atmosphere of HCl by post-depositional loss, perhaps implying an increased snow-accumulation rate ( Reference Legrand, Leopold, Domine, Wolff and BalesLegrand and others, 1996).

Further chemical and stratigraphic data are necessary to understand the chloride behaviour.

3.2. Special events

In a preliminary way, we report some examples of a detailed comparison between the electrical and chemical profiles, for peaks characterized by particular height and/or shape. We chose two volcanic events from the first 40 m depth, because their characteristic signals are recorded in all polar ice cores (Reference Hammer, Clausen and DansgaardHammer and others, 1980; Reference HerronHerron, 1982; Reference Legrand and DelmasLegrand and Delmas, 1987; Reference Delmas, Kirchner, Palais and PetitDelmas and others, 1992; Reference ZielinskiZielinsky, 1995; Reference Zielinski, Mayewski, Meeker, Whitlow and TwicklerZielinsky and others, 1996; Reference ClausenClausen and others, 1997) and their dating is well known. In Antarctica, the years of these signatures have been set by Reference Delmas, Kirchner, Palais and PetitDelmas and others (1992) from the sulphate profile of a 1000 year ice core drilled near Amundsen-Scott Station (South Pole). On the other hand, the third event was characterized by a particular pattern for chloride.

For the 0–100 m depth range, ECM measurements are shifted about 0.9 m with respect to the other parameters. In fact, the 0–100 m ECM profile was measured on a parallel ice core (Firetracc ice core), drilled during the 1998/99 campaign very close to the main Dome C ice core, for which the ECM profile was not measured. The Tambora eruption signal, described below, was used to estimate the depth shift between the two Dome G drillings (Firetracc and main Dome C ice core). Figure 4 shows the Tambora sulphate peak in the two ice cores. We can observe a close correlation between the two profiles, within the limits of the sample resolution (40 mm), but the Tambora peak is recorded in the Dome C ice core 0.86 m deeper than in the Firetracc ice core (comparison of DEP profiles for the two cores confirms this difference, also to within 40 mm).

Fig. 4. Dephasing between the Tambora records in the sulphate profiles from the (a) Firetracc and (b) Dome C ice cores.

Tambora signature

Figure 5 shows the ECM (a), DEP (b) and sulphate (c) profiles related to the unambiguous signal of the Tambora (Indonesia) eruption, recorded at 12.34m in the sulphate and DEP profiles. This eruption is dated to AD 1815 and the signature in Antarctic firn is set at 1816 by Reference Delmas, Kirchner, Palais and PetitDelmas and others (1992) in the South Pole core.

Fig. 5. Signatures of the Tambora eruption (AD 1816) in (a) ECM, (b) DEP and (c) sulphate profiles. The ECM profile is from the Firetracc ice core. The DEP and sulphate profiles were measured on the Dome Cue core.

The sulphate concentration reaches 606 μgL−1, about 7.5 times higher than the local background value (around 80 μg L-). The second peak, that characterizes the Tambora period, is at 12.68 m and its height is about 270 μg L−1. The sulphate ratio between the two peaks is 2.24. The DEP profile is coincident in depth and peak shape with that of sulphate, with a similar ratio between the two peaks, if they are measured with respect to the background values of about 5 × 106 μS m−1. The ECM peaks are shifted by about 0.9 m (coming from the Firetracc ice core, see above) and do not have the same relative heights as the DEP and sulphate peaks. We can observe that the two peaks have approximately the same height. In general, the ECM profile shows a higher background noise, with respect to the DEP, in the first 100 m section. Therefore, the ECM Tambora peak becomes less evident than in the DEP and, above all, in the sulphate profile.

AD 1259 eruption

Figure 6 shows an interesting series of peaks in the 36–42 m depth range. The same series is observed by Reference ClausenClausen and others (1997) in the Dye 3 1980 ice core. We can observe six well-defined sulphate peaks (Fig. 6c) the highest of which is located at 38.12 m, with a sulphate concentration (637 μg L–1) similar to that of the Tambora eruption. This peak is related to an unknown eruption (probably El Chichon in Mexico) whose signal was dated at AD 1259 by Reference Delmas, Kirchner, Palais and PetitDelmas and others (1992).

Fig. 6. AD 1259 eruption ( El Chuhon?) signature and adjacent peaks in (a) ECM (b) DEP and (c) sulphate profiles. The ECM profile is from the Firetracc ice core. The DEP and sulphate profiles were measured on Dome Cue core.

The DEP profile is surprisingly close to that of sulphate: all peaks are in-phase and the relative ratios between the peak heights are very similar. The ECM profile shows a similar pattern, too, with in-phase peaks (taking into account the shift between the two ice cores) and similar peak shapes, but with a higher background noise and some differences for the peaks to the left of the main peak. The good agreement between ECM, DEP and sulphate peaks demonstrates that all the peaks are caused by sulphuric acid from volcanic emissions.

103–109 m depth

Figure 7 shows a depth range where a particular chloride (Fig. 7d) pattern is recorded. At 104.48 and 107.52 m we can observe two high peaks of chloride reaching 95 μg L–1, about nine times as high as the background value (around 10 μg L−1 in this depth range). They are separated by four other lower peaks (about 40 μg L−1) set at similar intervals between them (around 0.7 m). The sulphate values (Fig. 7c) do not show any particular trend, with values close to the background level of about 90 μ L−1. A structure similar to that of chloride is also visible in the DEP and ECM profiles, in spite of the high background noise and some very narrow electrical spikes. In fact, HCl gives a higher ECM response with respect to sulphuric acid (Reference Legrand, Petit and KorotkevichLegrand and others, 1987). For this reason, we infer a dominant contribution of HCl to the electrical pattern of this ice-core section. The periodicity of HCl deposition calls for further study of the chemical composition of this depth interval (when the CFA and the discontinuous IC data are available), to understand the temporal trend of the source (volcanic activity?) and/or of the long-range-transport processes. On the basis of a preliminary time-scale (personal comunication from J. Schwander, 1999), the 104–108 m depth interval corresponds approximately to the time interval 2490–2620 BP.

Fig. 7. Depth profiles of (a) ECM, (b) DEP, (c) sulphate and ( d) chloride determinations at 103–109 m depth.

4. Conclusions

The ECM and DEP measurements, performed in situ, are able to give fast and continuous records of variations in the ionic content of the ice. By comparing them, it is possible to obtain information on the acidic or non-acidic components, because of the higher selectivity of ECM for H+. Nevertheless, for determining the dominant acidic species, such electrical measurements have to be followed by chemical analysis. In situ, continuous or fast semi-continuous chemical analysis constitutes, therefore, a complementary method to distinguish sulphuric, hydrochloric or nitric acids and to correlate the ice composition to the different sources and transport processes.

From the electrical and chemical profile for the first 400 m of the EPICA-Dome C ice core, some conclusions can be drawn:

Unlike the Greenland Holocene ice, where nitric acid is dominant, the main acidic species in the Antarctic Plateau is H2S04 , but some particular events are characterized by high HCl concentrations;

The ECM, DEP and sulphate profiles match very well, particularly for peaks coming from volcanic activity. Some differences are due to HCl deposition or to ice layers with a dominant contribution of non-acidic ionic species;

An increase with depth in the background values has been observed for chloride. This component also shows a progressive increase of data dispersion, in particular for the 300-400 m range;

Around 270–360 m depth, a further increase in chloride is visible. This trend confirms the previous observation reported by Reference Legrand and DelmasLegrand and Delmas (1988) from the old Dome C ice core. Further work is needed to determine whether this pattern is due to a change in the source or a change in climatic factors (transport or accumulation rate) affecting the amounts or speciation of deposited and retained chloride. In any case, it indicates a significantly different regime in the early Holocene compared to the later period;

Along the sulphate profile, many spikes were found, probably due to volcanic depositions, with concentration maxima up to 900 μg L–1 The shallower large peaks were identified by comparison with Antarctic and Greenland ice cores. When a reliable dating of the Dome C ice core is available, some of the unidentified peaks can be used as temporal horizons because of their characteristic shape or relative height.

Acknowledgements

This work is a contribution to the "European Project for Ice Coring in Antarctica" (EPICA), a joint European Science Foundation/European Commission (EC) scientific programme, funded by the EC under the Environment and Climate Programme (1994–98) contract ENV4-CT95-0074 and by national contributions from Belgium, Denmark, France, Germany, Italy, The Netherlands, Norway, Sweden, Switzerland and the United Kingdom. We thank our many colleagues involved in drilling, science and logistics at Dome C.

References

Clausen, H. B. and 6 others. 1997. A comparison of the volcanic records over the past 4000 years from the Greenland Ice Core Project and DYE 3 Greenland ice cores. J. Geophys. Res., 102(C12), 26,70726,724.CrossRefGoogle Scholar
Delmas, R.J., Kirchner, S., Palais, J. M. and Petit, J-R.. 1992. 1000 years of explosive volcanism recorded at the South Pole. Tellus, 44B(4), 335350.Google Scholar
Fuhrer, K., Neftel, A., Anklin, M. and Maggi, V.. 1993. Continuous measurements of hydrogen peroxide, formaldehyde, calcium and ammonium concentrations along the new GRIP ice core from Summit, central Greenland. Atmos. Environ., Ser. A, 27(12), 18731880.Google Scholar
Hammer, C. U., Clausen, H. B. and Dansgaard, W.. 1980. Greenland ice sheet evidence of post-glacial volcanism and its climatic impact. Nature, 288(5788), 230235.Google Scholar
Herron, M.M. 1982. Impurity sources of F., CI, N 0 3 and SO 4 in Greenland and Antarctic precipitation. J. Geophys. Res., 87(C4), 30523060.CrossRefGoogle Scholar
Legrand, M. 1987. Chemistry of Antarctic snow and ice. J. Phys. (Paris), 48, Colloq. CI, 7786. (Supplement au 3.)Google Scholar
Legrand, M. R. and Delmas, R.J.. 1987 A 220–year continuous record of volcanic H2S04 in the Antarctic ice sheet. Nature, 327(6124), 671676 Google Scholar
Legrand, M. R. and Delmas, R. J.. 1988. Soluble impurities in four Antarctic ice cores over the last 30 000 years. Ann. Glacial, 10,116120.Google Scholar
Legrand, M. and Saigne, C.. 1988. Formate, acetate and methanesulfonate measurements in Antarctic ice: some geochemical implications. Atmos. Environ., 22(5), 10111017 Google Scholar
Legrand, M., Petit, J. R. and Korotkevich, Ye. S.. 1987. D.C . conductivity of Antarctic ice in relation to its chemistry. J. Phys. (Paris), 48, Colloq. CI, 605611. (Supplement au 3.)Google Scholar
Legrand, M., Leopold, A. and Domine, F.. 1996. Acidic gases (HCl, HF, HN03, HCOOH, and CH3COOH): a review of ice core data and some preliminary discussions on their air-snow relationships. In Wolff, E.W. and Bales, R. C., eds. Chemical exchange between the atmosphere and polar snow. Berlin, etc., Springer-Verlag, 1943. (NATO ASI Series I: Global Environmental Change 43.)CrossRefGoogle Scholar
Lorius, G, Merlivat, L., Jouzel, J. and Pourchet, M.. 1979. A 30,000–yr isotope climatic record from Antarctic ice. Nature, 280(5724), 644648.Google Scholar
Moore, J. C., Wolff, E.W., Clausen, H. B. and Hammer, C. U.. 1992. The chemical basis for the electrical stratigraphy of ice. J. Geophys. Res., 97 (B2), 18871896. Google Scholar
Moore, J. C, Wolff, E.W., Clausen, H. B, Hammer, C. U., Legrand, M. R. and Fuhrer, K.. 1994. Electrical response of the Summit-Greenland ice core to ammonium, sulphuric acid, and hydrochloric acid. Geophys. Res. Lett., 21(7), 565568.CrossRefGoogle Scholar
Neftel, A., Beer, J., Oeschger, H., Zurcher, F and Finkel, R.C.. 1985. Sulphate and nitrate concentrations in snow from south Greenland, 1895–1978. Nature, 314(6012), 611613.Google Scholar
Saigne, C. and Legrand, M.. 1987. Measurements of methanesulphonic acid in Antarctic ice. Nature, 330(6145), 240242 CrossRefGoogle Scholar
Sigg, A., Fuhrer, K., Anklin, M., Staffelbach, T. and Zurmuhle, D. 1994. A continuous analysis technique for trace species in ice cores. Environ. Set. TechnoL, 28(2), 204209.CrossRefGoogle ScholarPubMed
Tabacco, I. E., Passerini, A., Corbelli, F and Gorman, M.. 1998. Correspondence. Determination of the surface and bed topography at Dome C, East Antarctica. J. Glacial, 44(146), 185191.Google Scholar
Wolff, E.W, Moore, J. C., Clausen, H. B., Hammer, C. U., Kipfstuhl, J. and Fuhrer, K.. 1995. Long-term changes in the acid and salt concentrations of the Greenland Ice Core Project ice core from electrical stratigraphy. J. Geophys. Res, 100(D8), 16,24916,263.Google Scholar
Wolff, E.W, Miners, W D, Moore, J. C. and Paren, J. G.. 1997 Factors controlling the electrical conductivity of ice from the polar τegions –a summary. J. Phys. Chem., 101(32), 60906094.Google Scholar
Wolff, E., Basile, I., Petit, J.-R. and Schwander, J.. 1999. Comparison of Holocene electrical records from Dome C and Vostok, Antarctica. Ann. Glacial., 29,8993.CrossRefGoogle Scholar
Zielinski, G A. 1995. Stratospheric loading and optical depth estimates of explosive volcanism over the last 2100 years derived from the Greenland Ice Sheet Project 2 ice core. J. Geophys. Res., 100(D10), 20,93720,955.Google Scholar
Zielinski, G.A., Mayewski, PA., Meeker, L. D, Whitlow, S. I. and Twickler, M. S.. 1996.110,000–yr record of explosive volcanism from the GISP2 (Greenland) ice core. Quat. Res, 45(2), 109118.Google Scholar
Figure 0

Fig. 1. Semi-continuous (1 measurement every minute) ion chromatogram of a section of EPICA-Dome C ice core. Expanded figure shows separation between chloride (1), nitrate (2) and sulphate (3) peaks.

Figure 1

Fig. 2. Depth profiles of (a) ECM, (bDEP and (c) sulphate determinations in Dome Cue core at 100–200 m depth.

Figure 2

Fig. 3. Depth-concentration profile of chloride in Dome Cue core at 200–400 m depth.

Figure 3

Fig. 4. Dephasing between the Tambora records in the sulphate profiles from the (a) Firetracc and (b) Dome C ice cores.

Figure 4

Fig. 5. Signatures of the Tambora eruption (AD 1816) in (a) ECM, (b) DEP and (c) sulphate profiles. The ECM profile is from the Firetracc ice core. The DEP and sulphate profiles were measured on the Dome Cue core.

Figure 5

Fig. 6. AD 1259 eruption ( El Chuhon?) signature and adjacent peaks in (a) ECM (b) DEP and (c) sulphate profiles. The ECM profile is from the Firetracc ice core. The DEP and sulphate profiles were measured on Dome Cue core.

Figure 6

Fig. 7. Depth profiles of (a) ECM, (b) DEP, (c) sulphate and ( d) chloride determinations at 103–109 m depth.