Þorsteinsdóttir et al. consistent with the idea that external water existed at the eruption site during the eruption. In this particular case the external water is glacier melt water. When external water and high viscosity magma come together in an eruption vast amount of fines are produced (Self and Sparks, 1978) which is likely in the case of the SILK-LN tephra layer. According to Rose and Durant (2009) silicic eruptions produce high proportions of fine material (30 to >50%) in compari- son to basaltic eruptions (∼1 to 4 %). The upward coarsening of the SILK-LN tephra could reflect changes in the eruptive behaviour, ei- ther increased vigour carrying larger grains higher and thereby increasing their range of flight or less effec- tive fragmentation due to isolation of the magma/vent from the melt water or due to draining of water in a jökulhlaup, allowing formation of larger grains in the later stages of the eruption. Stronger wind during the latter part of the eruption could also have increased the range of flight resulting in deposition of more coarse grained tephra at any given location. No internal layering was observed within the Hekla 1947 tephra layer in the field in 2013 and only bulk samples were collected. According to Thorar- insson (1954, 1968) changes with time were observed at several locations where the Hekla 1947 tephra was collected freshly fallen. In the samples measured by Thorarinsson (recalculated for this study) the mean grain size of the lower unit was -1.00 Φ (2 mm), -0.07 Φ (1.04 mm) and 1.19 Φ (0.44 mm) at 32, 49 and 68 km, respectively and that of the upper unit was -0.01 Φ (1.00 mm), 0.48 Φ (0.71 mm) and 2.62 Φ (0.16 mm) at the same locations (Figures 11 and 14). Hekla is not covered with a glacier although perennial snow was present and there is not sufficient amount of water in the area that could have caused a hydromagmatic eruption. The coarse grained grey brown tephra in the bottom unit was most likely pro- duced during a magmatic eruption (dry eruption) such as is common with Hekla volcano. The change to finer brownish black tephra was related to decreasing SiO2 content (Þórarinsson, 1968) and most likely to lower eruption column. Grain morphology The grain shape results show a difference between the Hekla 1947 and SILK-LN tephra layers. In the case of the ruggedness there is not a significant difference between Hekla and Katla tephra. In fact the rugged- ness value of Hekla 1947 samples lies between the two SILK-LN samples (Tables 1 and 2). There is a prominent difference between the elon- gation values of the Katla tephra and the Hekla tephra (Figure 16). The Katla grains have much more elon- gated shape than the Hekla grains that have more equant and stocky shape. The elongation values in the Hekla tephra are exactly the same at a location close to the source and at a location further away whereas those of the Katla tephra change with distance. The Katla grains that travel furthest from the source have smoother surface and more elongated shapes while the ones traveling shorter distances have more uneven surfaces and are less elongated. Therefore it appears that small, elongated, smooth surfaced grains settle 0,40 0,50 0,60 0,70 0,80 0 20 40 60 E lo n g at io n Dis tanc e from s ourc e (km) E longation vs dis tance Geldingasker middle unit Geldingasker bottom unit Varmárfell middle unit Varmárfell bottom unit Vestan Hafrafells Hamragarðaheiði Figure 16. Elongation parameters of the SILK-LN tephra (triangles) and Hekla 1947 tephra (circles) plotted against distance. Lower values represent more elongated grains. – Ílengd SILK-LN gjósku (þríhyrningar) og Heklu 1947 gjósku (hringir) á móti fjarlægð. Lægri gildi – ílengri korn. 44 JÖKULL No. 65, 2015

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