TABLE 2. mg/1 1. 2. 3. 4. Si02 512.0 170.0 171.0 15.2 Na 242.0 64.4 406.0 10.0 K 32.0 1.5 29.0 0.9 Ca 1.0 1.6 136.0 8.5 Mg- 0.1 0.5 32.0 2.5 C1 267.0 28.4 84.0 6.0 F 2.1 1.0 2.2 0.25 SO4 57.3 18.7 38.0 10.2 HCO3 9.8 47.6 CO3 48.6 50.4 OH 23.5 Diss. solids 1221.0 340.0 1660.0 76.0 T°C 100.0* 100.0** 41.0 P" 9.75 9.4 6.4 7.35 1. Hveragerði, drillhole G-8, 3. 1. 1963. 2. Reykjavík, drillhole G-4, 21. 7. 1960. 3. Lýsuhóll, carbonated spring, 30. 9. 1958. 4. Múlakvísl, glacier river, 1. 10. 1963. *) Base temperature 230° C. **) Base temperature 146° C. calcium, magnesium and bicarbonate are more similar in amount to waters of carbonated springs. The only component of the analysis in Table 1 which might be looked upon as magmatic in origin is bicarbonate (i. e. COo). During the jökulhlaups, however, considerable amounts of SOo and H^S are released, but the amounts is not known. Sorne of the sulfate in the water is probably oxidized SO2 or H2S, but the amount is linrited by the amount of oxvgen present in the ice. The presence of sulphur dioxide lias not been proven analytically, but its distinct smell is a relatively good indicator. Ellis (1959) nrade theoretical calculations on the composi- tion of gasmixtures similar in molecular conr- position to volcanic and geothernral gases, at various temperatures and pressures. At low to medium pressures SOo is the dominant sulphur component at high temperatures, but the amount of H2S increases with lower tempera- tures. The theoretically predicted compositions compare well with actually nreasured gasmix- tures such as the volcanic gases from Surtsey, where SO2 is the dominant sulphur conrponent at 1100° C. (Sigvaldason and Elísson 1966). In the Icelandic geothermal areas, SO2 has never been found and here the highest measured tenrperatures are 230° C. (Böðvarsson and Pálmason 1961). The presence of SOo in the gases from Grínrsvötn would therefore indicate higher temperatures than found in otlrer high temperature areas in Icalend. An interesting aspect of this phenomenon is the buildup of the chemical concentration in the lake water during a known length of time. The concentration of the Sept. 6th sample is in some aspects conrparable to low temperature thermal waters in Icelancl, which are believed to be in equilibrium with the wallrock at depth, at a temperature of 150 to 170° C. The base temperature in the Grímsvötn area is probably JÖKULL 127

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