pp. 314—319) suggested that an eruption took place in Hveradalur (Solfatara Valley) in Kverk- fjöll in 1938 whereas Thorarinsson (1950) claims that untenable on tephrochronological grounds, and suggests an eruption there in 1929. How- ever, the area is clearly very active still, as abundantly evident from the liydrothermal activity in Hveradalur, which in terms of energy output is amongst the strongest in Iceland. LAKAGÍGAR. The eruption of 1783 is the largest known basaltic eruption in recorded history, and the most catastrophic one in Ice- land (Table II, nr. 10). The fissure extends beneath the Vatnajökull ice slieet, which must liave resulted in tephra-formation. In the light of tlie present events at Krafla in northern Iceland (Björnsson et al. 1977) the possibility lias been considerecl by rnany Ice- landers that the Lakagígar Fires were produced by the lateral drainage of the Grímsvötn magma chamber, in consequence of an episode of spreading on the eastern volcanic zone. This hypothesis is supported by a number of petro- chemical arguments: The chemical composition of the Lakagígar lava and the Grímsvötn pro- ducts is similar; such “developed” chemistry is out of equilibrium with a supposed source in the mantle; the oxygen-isotopic composition of the Lakagígar lava (Muehlenhachs et al. 1974) is indicative of a long magmatic development in the crust; and, finally, the parallel Eldgjá fissure, about 5 km distant from the Lakagígar one, has totally different chemical characterist- ics, that of Katla. It is almost inconceivable that these two fissures, parallel but 5 km apart, that erupted within 900 years of each other producing totally different magmas, could be derivetl straight from a heterogeneous mantle. There are many problems, however, to con- sider, not least the volume of the Lakagígar flow, which is about 13 km3. This is equivalent to a sphere of 1.45 km radius, or a cylinder of 35 km2 cross section and 370 m depth (the area of Grímsvötn is 35 km2). The average depth of the Grímsvötn caldera is about 300 m — the bottom is at about 1000 m altitude above sea level, whereas the altitude of the rim ranges from 1100 m in the east to about 1700 m in the south, or about 1300 m on the average. There is no question, however, of the caldera having formed in 1783 — it was described long before that. Furthermore, the 10-year period of Grímsvötn jökulhlaups liad been established long before the 1783 eruption, and in general the behaviour of both the caldera and the Gríms- vötn volcano seems to have been unaffected by the Lakagígar eruption. On the other hand, the shape of the Grímsvötn caldera suggests that it may be composite (Thorarinsson 1978, pers. connn.), and the northern part could liave forrn- ed in 1783 without altering the pattern of either jökulhlaups from Grímsvötn or eruptions there. Another fissure eruption in the area west of Vatnajökull is that of TRÖLLAHRAUN 1862- 64 (Thorarinsson ir Sigualdason 1972, see Table II, no. 7). This eruption was formerly thought to have taken place within the Vatnajökull ice sheet (Thoroddsen 1924), or on Dyngjuháls (Jónsson 1945). Little tephra was produced in the eruption, which lasted intermittently for 27 months — only two eruptions in Iceland are known to have lastecl longer during the 1100 years of settlement (Tliorarinsson ir Sigvalda- son, op. cit.). ASKfA or DYNGJUFJÖLL, some 60 km to the north-east of Bárdarbunga, erupted in 1961 (Thorarinsson ir Sigualdason 1962, Table II, no. 1), giving rise to a relatively small basaltic lava flow. The tephra from this eruption forms the uppermost layer in the Bárdarbunga core. This area was very active in the nineteen twenties, but by no means all the eruptions taking place then were noticed until “after the fact”, by the presence of the new lava flows where none existed before (Jónsson 1945; Thorarinsson 1963). This underscores the fact tlrat during the centuries represented in the Bárdarbunga core, countless eruptions could liave taken place in Dyngjufjöll without theirs being recordecl at all. The Askja eruption of 1875 struck a calamity in large areas of eastern Iceland, and drove the population frorn those parts to America by the hundreds (Thorarinsson 1944). However, as a precursor to that great explosive silicic volcan- ism, wliich started on March 28, 1875, had been more than three months of earthquakes, and over a year of increased hydrothermal activity in Askja (Thorarinsson 1963). Tliere is evidence, JÖKULL 27. ÁR 9

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