Grain characteristics of tephra from Katla and Hekla eruptions grains. Plume height, eruption intensity, changes in wind strength and fragmentation are all factors that influence the way of transport and how far the grains have travelled (e.g. Sparks et al., 1981; Carey and Sparks, 1986; Dellino and Volpe, 1996; Rose and Du- rant, 2009; Bonadonna and Haughton, 2005; Eiríks- son, 1993; Guðmundsdóttir, 1998; Óladóttir, 2003; Þorsteinsdóttir, 2012). Grain morphology analysis Grain morphology analysis was carried out on se- lected samples from both the H-1947 and SILK-LN tephra. The parameters ruggedness, elongation and circularity were measured using an image analyzing program (Eiríksson et al., 1994). The Hekla tephra was cleaned using an ultrasonic bath to remove or- ganic material adherent to the grains but no cleaning was needed for the Katla tephra. Tephra grain morphology has been used to study whether the grains are a product of fragmentation by hydromagmatic activity or due to exsolution of magmatic gases and to distinguish between different phases within an eruption (e.g. Eiríksson and Wigum, 1989; Dellino and Volpe, 1995; Gudmundsdóttir, 1998; Óladóttir, 2003; Dellino and Liotino, 2002; Büttner et al., 2002; Þorsteinsdóttir, 2012; Cioni et al., 2014). Grain morphology studies have also been used to investigate the aerodynamic properties of tephra particles, i.e. how far and for how long they stay up in the air. Mele et al. (2011) concluded that settling ve- locity of tephra grains is highly influenced by shape, not only size and density. Scanning electron microscopy SEM (scanning electron microscope) images were taken on a TM3000 electron microscope (Hitachi High-Tech. Corp. 2010) on selected Hekla 1947 and silicic Katla tephra samples. The purpose was to demonstrate potential differences between the tephra produced in these two volcanoes that might reflect the different eruptive environments. RESULTS – THE SILK-LN TEPHRA Field characteristics Field observations of the SILK-LN tephra show changes in macroscopic characteristics i.e. bedding, grain size, colour etc., within and between sample lo- cations (Figure 2). Altogether 23 samples were col- lected at ten locations. At four locations, Loðnugil, Geldingasker, Leiðólfsfell and Varmárfell, the tephra was bedded and sample from each unit was collected. Where no bedding was apparent only a bulk sam- ple was collected. All the samples were analysed for grain size and the results plotted as histograms show- ing mean grain size, sorting and Wt% of fines ≤0.063 and ≤0.011 mm. All histograms and tables appear in Þorsteinsdóttir (2015). The SILK-LN tephra is olive- to greyish green and bedded where it is undisturbed. Figure 3 shows the tephra layer at Loðnugil. Elongated, "needle"-shaped grains with drawn-out (elongated) vesicles are promi- nent but denser grains are also present. Both grain size and colour change with time, the darkest layer being the most coarse grained. Grain size characteristics Results from Loðnugil demonstrate the changes in grain size distribution in the SILK- LN tephra with time (Figure 6). In the two lowermost units the grains are mostly smaller than 1 mm with a distinct peak be- tween 0.25 and 0.125 mm, the mean grain size is 0.15 and 0.14 mm and the largest grains 1–1.5 cm. The two upper units are bimodal with additional peaks at the coarse part of the histograms, between 2–4 and 1– 2 mm respectively. The largest grains are over 2 cm in diameter. At the four locations where the tephra layer was bedded the amount of fine ash ≤0.063 mm changed from ca. 30–43 Wt% in the bottom unit, to 25–40 Wt% in the middle unit and to ca. 11–29 Wt% in the top unit. Changes in mean grain size with distance (22– 65 km from center of caldera) along the axis of thick- ness are shown on Figure 7. Individual units are shown separately. Mean grain size changes from 0.14–0.43 mm at 22 km to 0.19–0.10 mm at 65 km. Largest grains change from cm-sized clasts at 22 km to mm-sized grains at 65 km. The mean grain size of the bottom units is halved every 70–75 km whereas that of the coarser units appears to be halved every 20–22 km. JÖKULL No. 65, 2015 35

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