Table IV. Analytical methods. — Efnagreiningaaðferðir. Element PH Na K Ca Mg C1 S04 F Si HCO3 Analytical Method Relative error a Reference Combination pH glass electrode High pressure liquid ion chromatography 3% High pressure liquid ion chromatography 7% Atomic absorption spectrophotometry 19% Skougstad et al. (1979) Atomic absorption spectrophotometry 7% Skougstad etal. (1979) High pressure liquid ion chromatography 29% High pressure liquid ion chromatography 34% Ion sensitive electrode Skougstad etal. (1979) ”Spectrophotometric, molybdate blue“ 20% Skougstad et al. (1979) ”Calculated, assuming pure water and air“ Plummer and saturation at the measured pH and temperature. Busenberg (1982) “The relative error for C1 and SO4 is the maximum one between two of up to 16 replicates. 1987-1988 precipitation layer can be studied by sam- Ples 88-1.1, ”88-2.1“, ”88-3.0“, 88-4.1, 88-5.1, 88- 6-l, 88-7.1, 88-8.1, 88-9.1 (Table I, Fig. 2). The pH °f what is left of the 1987-1988 layer, at the time of sanrpling, ranges from 5.47 to 5.73. The pH is highest ln eore 9 which is closest to the edge of the glacier but Ihe pH reaches lowest value in core 7 at 1300 m.a.s.l. altitude. At higher altitude it ranges from pH 5.50 ,0 5.67. Chloride is always the most important anion 6ut of the cations the sodium ion is the predominant °ne. This suggests a primary marine origin of the ions. The concentration of dissolved sea-salts increases with mcrease in altitude, contrary to what has been docu- fiiented for precipitation in Iceland and other parts of the world (Sigurðsson and Einarsson, 1988; Herron and Langway, 1985). The concentration of chloride 'h the 1987-1988 layer is greatest near Grímsvötn, 6-9 ppm (samples 1.1 and ”2.1“, Table I and Fig. 2) but decreases downslope towards west and is at its minimum, 0.3 ppm Cl” in core 9 closest to the base °f the glacier at 1120 m.a.s.l. (sample 9.1 in Table 1 and Fig. 2). The concentrations of dissolved silica and fluorine are at or below the detection limits of the analytical methods where tested (Table I). Downcore changes in pH, Na+ and Cl“ are shown in Fig. 4 for core 1 an(j jn pjg g for core 2 but down- c°re concentrations for other chemical constituents are shown in Table II for core 1 and Table III for core 2. The pH is highest in the top part of core 1 (Fig. 4), it decreases gradually down to about 140 cm depth where the pH is equal to 5.4. Below this level down to the bottom of the 1987-1988 precipitation layer the pH ranges from 5.4 to 5.5. There is an abrupt shift to a higher pH at the top of the 1986-1987 precipitation layer (Fig. 4). The pH is always higher in the older layer if the first two samples in the younger layer are excluded. The chloride and sodium ion concentrations vary with depth in similar manner as described for the pH. The concentrations are relatively low at the top of the core, they reach maximum at about 190 cm depth and the ion concentrations in the 1986-1987 precipi- tation layer are lower than in the 1987-1988 precipi- tation layer above. Similar trends can be observed in core 2 (Fig. 5). The ion concentrations reach maxi- mum at 190 cm depth but that is the depth at which the cores were below 0°C at the time of sampling. All the cores shown in Figs. 4, 5, and 6 have un- dergone partial melting. The core taken closest to the edge of the glacier, core 9 (Fig. 2), have undergone more melting than cores from higher levels. When collected, cores 1 and 2 were frozen below 190 cm depth. In other words, cores 1 and 2 have undergone partial melting down to about 190 cm depth and the lower parts of the cores represented by the 1986-1987 precipitation layer have undergone partial melting dur- ing the summer 1987. Core 9 is partially melted down JÖKULL, No. 40, 1990 105

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