Holocene eruptions within the Katla volcanic system, pumice volumes or the floods that transported them were particularly large. Predominantly or partly effusive basaltic eruptions Major events: The "Fires" Effusive basaltic eruptions are the least common events on the Katla volcanic system. Between 5 and 10 relatively minor eruptions, that were at least partly effusive and produced small lava flows, and two major "fires" producing large lava flows, are known to have taken place during the Holocene. The former occurred on short fissures on the western and northern periph- ery of Mýrdalsjökull central volcano and are thought to be more than 4000 14C yrs old (Jóhannesson et al., 1990). In the two "fires", fissures also opened up on the NE trending fissure swarm. They are the largest and most hazardous Holocene events of the Katla vol- canic system. This chapter focusses mostly on the younger fires. The older "fires" (Hólmsá fires) are about 6800 14C yrs old. The lava flows, now partly covered by the products of the younger fires, can be shown to fit into the regional tephra stratigraphy of S-Iceland at a specific stratigraphical level (Figure 5). The lavas fol- lowed depressions and river channels down the Álfta- versafréttur area at least as far as Atlaey (Figure 8) and possibly all the way to the coast of that time. Their southward extension is hidden below an exten- sive cover of younger lava. The volume of lava is ten- tatively estimated to be ca. 5 km . The length of the eruptive fissure is not known, but a minimum length of 8-10 km outside the present ice margin near Öldufell is inferred by the paths taken by the lava. The younger "fires" (Eldgjá eruption) took place in the early 10th century (Larsen, 1979), most likely around 934-938 AD (Hammer et al., 1980; Zielin- ski et al., 1995). The ca. 75 km long fissure extends from the Katla caldera beneath the Mýrdalsjökull ice cap in the southwest, through the mountainous terrain northeast of the ice cap to Eldgjá proper and contin- ues intermittently to Stakafell mountain (Figure 8). It is the longest known eruptive fissure to be active in historical time (last 11 centuries). The eruption pro- duced a widespread basaltic tephra layer, composed of several distinct units, and two major lava fields (Rob- son, 1957; Miller, 1989; Larsen, 1996; Thordarson et al., in press). Possibly, a hyaloclastite flow accom- panied the eruption. Jökulhlaups occurred along the subglacial part of the fissure. The Eldgjá event is of particular importance be- cause of its magnitude and because it is the cause of the most extensive environmental changes brought about by volcanic activity in Iceland during the last 11 centuries. The Eldgjá fires of the 10th century: The fissure and the products About one-fifth of the total length of the Eldgjá fissure lies below the present Mýrdalsjökull ice cap. The ex- act locations of the subglacial fissure segments are not known but isopachs of individual units of the Eldgjá tephra layer define at least two major segments. The southwesternmost of the two is located to the west of Kötlujökull, lying either within the present caldera or along its eastern margin/fracture. Another major seg- ment lies to the west of Öldufellsjökull, possibly sepa- rated from the adjoining subaerial segment by a minor discontinuity or a dextral shift. The 60 km long subaerial part of the fissure runs through hillocky landscape and becomes increasingly discontinuous to the northeast (Figures 1 and 8). In- dividual fissure segments occupy the low areas and are connected by shallow graben structures extend- ing across topographical highs. Locally the fissure opened up in a pre-existing valley or a depression. This section of the eruption fissure is an 8 km long, 400 m wide and 150 m deep chasm after which the eruption is named, Eldgjá proper. The depression was occupied by a river at the time of eruption as evi- denced by the scarps of a pre-eruption waterfall which was sealed off by the eruption products in the NW- wall of the chasm, close to the present waterfall. By far the greatest part of the airborne Eldgjá tephra was erupted on the subglacial part of the Eldgjá fissure (Figure 9). Hydromagmatic explosive activity appears to have been dominant throughout the erup- tion there. Isopachs of the tephra layer as a whole in- dicate that the main source area of the airborne tephra was west of Öldufellsjökull. Isopachs of individual units show that the first tephra to become airborne emerged there and at S-Eldgjá. JÖKULL No. 49 13

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