minerals. This reflects the state of the magma at the time of the eruption with the glass having the same composition as the liquid except the vola- tiles that have escaped. In the present study only the glass phase was analyzed using an ARL-SEMQ microprobe. Only clear siderome- lane was analyzed, about ten spots 5-10 microns in diameter, in each thin section. These analyses are therefore not the same as conventional whole rock analyses but as the mineral content is low in the samples, less than 5%, the difference will be fairly small. The advantage of the glass analyses is that it represents the liquid composition and is not affected by differential movement of liquid and minerals during the eruption. In black tachylitic glass, oxides have crystallized making them unsuitable for microprobe analyses but in most of the samples clear sideromelane is the dominating glass phase. DESCRIPTION OF SAMPLES ANALYZED The samples analyzed were collected by various people during an expedition to Gríms- vötn during the middle of June 1983. They are listed in an appendix. Most of the samples were collected from the northern tephra fan in differ- ent places. Continuous snow cover of the caldera wall above the lake and the presence of volcanic bombs but absence of hyaloclastite fragments makes it unlikely that any of the material in this fan originates from the caldera cliffs. One sample comes from the southern air-borne tephra fan and two from the eastern fan. For comparison samples available from the 1934, 1922 and 1903 eruptions were also in- cluded. The eruption in 1934 was a sizable one with the same main eruption site as in 1983. Tephra fell in eastern and north-eastern Iceland (Thórarinsson 1974) and samples collected at six distant weather stations on Easter Day, April lst are included. Samples were also collected close to the eruption site and are included but the exact date is uncertain. One dated and one undated samples from the 1922 eruption were also available. In 1903 erup- tions took place near Thórdarhyrna (Thórarins- son 1974) and in Grímsvötn (Jóhannesson 1983). The one sample available from this is most likely from Grímsvötn. The samples from the 1983 eruption contain only minor amounts of mine- rals, less than 5%. These are small grains of mainly plagioclase with additional olivine and pyroxene. The one exception from this is sample 0013 which contains a noticeably greater amount of these minerals but this is not reflected in the composition of the enclosing glass. The samples from the 1934 eruption are simi- lar, mainly glass with small amount of the same minerals. The samples 0024—0029, collected at the distant weather stations, are all identical with very fine grained glass and small amount of small plagioclase but little or no olivine and pyroxene, possibly due to eolian differentiation. Samples 0018 and 0019 contain mainly black tachylitic grains with very subordinate amounts of clear sideromelane so the homogeneity of these sampl- es is less certain than in the other samples. In the 1922 samples the same minerals are found but sample 0007 has markedly higher mine- ral content which again is not reflected by any difference in the enclosing glass. The 1903 sample contains small amounts of crystals, mainly plagioclase. CHEMICAL COMPOSITION OF THE GLASS The 1983 eruption. All the analyses are listed in Table 1 and it should be emphasized that these are analyses of the glass phase but not the whole rock. All the analyses show very similar chemical composition. The rock type is an evolved quartz normative tholeiite and similar tholeiites characterize many central volcanoes in Iceland. The chemical composition of the different sam- ples is very similar but small scale differences seem to be present. The results for one oxide can by considered at the time and the variation is no greater than could be expected if the same sam- ple was analyzed repeatedly at different times. If, however, it is considered that all the samples were analyzed during the same period under very similar conditions then it becomes more likely that minor compositional differences are actually present. If the variation of all the oxides is con- sidered together certain correlations would be expected. In other basalt suites certain trends are generally present and explained by mineral-liquid control likely to operate during the evolution of JÖKULL 34. ÁR 5

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