Einarsson and Hjartardóttir is inherited from, and reflects the original coastline or the original shelf edge. The N-S extension across the Eyjafjallajökull rifts is thus the result of minor slump- ing of the south flank towards the oceanic side. The north flanks are buttressed against the pre-existing landmass (Figure 5). Similar explanations were pro- posed by Fiske and Jackson (1972) for the location and orientation of the rifts of the Hawaiian volca- noes. According to their ideas each new volcano of the Hawaiian chain was built up on the flank of the preexisting volcanoes and the orientation of the new rifts was governed by the gravitational effect and the buttressing effect of the preexisting edifice. Similar conditions may arise where a new volcano is formed at the tip of a propagating rift. Today the Eyjafjalla- jökull edifice is buttressed on the SW-side by the ad- dition to the insular shelf area produced by the young Vestmannaeyjar volcanic system, that did not exist during the main building phase of Eyjafjallajökull. The westwards divergence of the faults and erup- tive fissures of the western fissure swarm is a remark- able feature of the volcano. Since dikes and eruptive fissures generally tend to form at right angle to the least compressive principal stress, the fissure swarm pattern should reflect the stress field. Nakamura et al. (1980) showed how the local stress field of a vol- cano dominates the fissure pattern in the central part of a volcano, but farther away the regional stress field takes over and the fissure pattern begins to reflect the regional stress. Under these conditions the fissure pattern is radial close to the volcano and parallel far- ther away, opposite to what we observe in the western branch of the Eyjafjallajökull fissure swarm. The fis- sures become more radial with increasing distance. This is an argument for a weak influence of the re- gional stress field. We suggest that the fissure pattern is the result of topographic influence through gravity. The eruptive fissures tend to form perpendicular to the elevation contours on the lower flanks of the volcano. This is in line with recent papers that show a strong topographic control on the propagation of dikes be- neath volcanic edifices. The horizontally propagating dike from Bárðarbunga volcano in August 2014 was shown to follow a path of maximum gradient in po- tential energy along its way to feed the Holuhraun eruption at a distance of 45 km from the center of the volcano (Sigmundsson et al., 2015; Heimisson et al., 2015). Even gently sloping flanks of mono- genetic lava shields have been shown to influence the intensity of fissure swarms that pass through them (Hjartardóttir and Einarsson, 2015). Figure 5. A North-South topographic profile through Eyjafjallajökull and surrounding area. The buttressing effect of the Tindfjallajökull volcano is evident, also the lack of support on the south side. – Þversnið með N-S stefnu í gegnum Eyjafjallajökul og nærliggjandi svæði. Sjá má hvernig Tindfjallajökull styður við norðan megin, en stuðning vantar við suðurhlíðar fjallsins. 10 JÖKULL No. 65, 2015

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