Einarsson and Hjartardóttir summit region, about 15 km to the west and 10 km to the east where it merges with the edifice of the neigh- bouring Katla volcano. There is a notable difference between the eastern and western fissure swarms. The E-W structural grain is strong in the eastern swarm. Eruptive fissures in the col between the two volca- noes (Fimmvörðuháls) are mostly E-W striking, and so are the normal faults that are prominent in the area. Hyaloclastite ridges formed by subglacial fis- sure eruptions on the SE-flank also have a strong E-W strike. The western fissure swarm, on the other hand, shows a divergent pattern towards the west. Fissures along the main ridge of the edifice trend E-W, but fis- sures on the side of the ridge have an arcuate shape. This is most prominent in the Skerin fissure on the NW-flank, thought to be the source of the eruption around the year 920 AD (Óskarsson, 2009), but is also seen in older fissures on the SW-flank. On the NW-flank the fissures are concave to the north, on the SW-flank they are concave to the south. It is noteworthy that the two short eruptive fissures active in the Fimmvörðuháls flank eruption of March- April 2010 had strikes that are inconsistent with the general E-W structural grain. Although the fissure swarms, or rift zones, of Eyjafjallajökull are distinct and well defined, their characteristics are different from those of the typical fissure swarms of the divergent plate boundary defor- mation zones. At Eyjafjallajökull they are defined by the orientation of eruptive fissures and the preferred location of eruption sites on the eastern and western flank of the volcano. The rift zones or the fissure swarms do not extend beyond the volcano’s edifice. A typical fissure swarm at a divergent branch of the plate boundary, such as the Askja and Kverkfjöll fis- sure swarms in the Northern Volcanic Zone (Figure 1) contain long normal faults and open fissures, in ad- dition to eruptive fissures (Hjartardóttir et al., 2015; Hjartardóttir et al., 2009; Hjartardóttir and Einarsson, 2012; Hjartardóttir et al., 2012). They also extend for tens of kilometers beyond the edifice of the central volcano of the respective system. The rift zones of Eyjafjallajökull thus show evidence of weak tectonic control, as opposed to the strong tectonic influence on the volcanic systems at the divergent plate boundary. MORPHOLOGY The Eyjafjallajökull edifice has the shape of an elon- gated, relatively flat cone that rises about 1,650 m above the coastal plain. The volcano is capped by a glacier, from which the volcano takes its name (jökull in Icelandic is glacier). The glacier is up to 200 m thick (Guðmundsson and Högnadóttir, 2005). The volcano has an elliptical 2.5-km-wide summit crater or caldera. The outlet glacier Gígjökull originates in the summit crater and flows towards the north through an opening in the crater rim. In the classification scheme of Icelandic volcanoes Eyjafjallajökull was frequently called a stratovolcano, mainly with refer- ence to its mixed eruptions of lavas and tephra (e.g. Thórarinsson, 1960; Saemundsson, 1978, Gudmunds- son, 2000). Jakobsson (1979) pointed out, however, that morphologically Eyjafjallajökull is comparable to Hekla, which is classified as a stratified ridge due to its elongated shape. Indeed, the aspect ratios of the two volcanoes (long axis divided by the short axis) is quite similar. For Eyjafjallajökull it is 2.5 measured at 1100 m elevation contour, for Hekla it is 2.4 at 1000 m. So, if anything, Eyjafjallajökull is a bit more elongated than Hekla. Slope has been used to classify volca- noes, particularly to distinguish between stratovolca- noes and shield volcanoes. Because of the elongated shape of Eyjafjallajökull the slopes are quite different along the long or short axes of the volcano. We find an average slope of 0.20 along the short axis (N-S) and 0.09 along the long axis (E-W). These slopes are com- parable to that of some of the Hawaiian shield vol- canoes. Thordarson and Larsen (2007) point out the close morphological resemblance to the polygenetic Hawaiian shield volcanoes and call Eyjafjallajökull "a shield-like volcano". Then, Thordarson and Hösk- uldsson (2008) classify Eyjafjallajökull as a shield volcano. We concur with this idea and emphasize the resemblance of Eyjafjallajökull to the Kohala volcano in Hawaii. The likeness is striking with respect to di- mensions, shape and structure. Both volcanoes are about 1600 m a.s.l. and have an uncertain extension below sea level. The elongation is about the same, similarly the slopes. The rift zones have similar ap- pearance and structure. 6 JÖKULL No. 65, 2015

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