Agustsdottir et al. eruptions (Sæmundsson, 1991), including the forma- tion of Hraunbunga, a small dacitic dome or coulee. Geological framework of studied formations In this study three well-defined domes were surveyed, Hlíðarfjall, Hrafntinnuhryggur and Hraunbunga (Fig- ure 1): 1. Hlíðarfjall (rhyolite, 310 m high, 2 km long) formed 90 000 years BP, parallel to the Krafla caldera rim on the southwest side (Sæmunds- son, 1991; Sæmundsson et al., 2000). 2. Hrafntinnuhryggur (rhyolite, 80 m high, 2.5 km long) formed 24 000 years BP, located 0.5–1 km inside and sub-parallel with the eastern caldera rim of Krafla (Sæmundsson, 1991; Sæmunds- son et al., 2000). 3. Hraunbunga (125 m high, 1.8 km long), a dacitic coulee erupted from a short fissure formed 10 000 years BP in the Heiðarsporður volcanic system (Sæmundsson, 1991). Hlíðarfjall and Hrafntinnuhryggur are short, steep ridges that may be regarded as subglacial equivalents of lava domes. Hlíðarfjall together with the domes Jörundur and Rani are parallel to the Krafla caldera rim and may, on the basis of composition and age, be interpreted to represent a common short-lived phase in Krafla’s history. It has been suggested that these rhy- olite eruptions were caused by the emplacement of a ring dike (Jónasson, 1994) but the activity may have been more limited and localised, associated with oc- casional rhyolitic dike intrusions. Hrafntinnuhrygg- ur has a different composition and age and is paral- lel to the tectonic trend in the caldera and subparal- lel with the eastern caldera rim (Sæmundsson, 1991). Hraunbunga is a dasitic coulee in the Heiðarsporður volcanic system; one of the few silicic domes in Ice- land not associated with a central volcano (Jónasson, 2007). METHODS AND DATA In general, silicic rocks have lower densities than those of a more basaltic composition. Measuring a gravity profile over a rhyolite dome surrounded by basaltic lava should demonstrate a significant den- sity contrast. The form of gravity anomalies associ- ated with outcropping surface formations can often be used to determine whether they are partly buried by younger formations or not (Figure 2). Knowl- edge of past geological processes at the observation site also gives an idea of what can be expected under the surface. Data from boreholes that reach to just over 2 km depth in the Krafla caldera demonstrate that bedrock in the region consists predominantly of basalt, with suites of layered piles of alternating lava and units of hyaloclastite down to 2000 meters, where granophyre becomes dominant at the bottom (Gud- mundsson et al., 2008; Arnadottir et al., 2009). The gravity surveys In Iceland, gravity studies aimed at determining bulk density of individual topographic features have been done on hyaloclastite tindars (hyaloclastite ridges), tuyas and lava flows but not on silicic formations. This study will attempt to fill that gap. The Nettle- ton method has proved to be useful for density determinations of hyaloclastite and lava formations (Schleusener et al., 1976; Gudmundsson and Milsom, 1997; Gudmundsson et al., 2001; Gudmundsson and Högnadóttir, 2004; Schopka et al., 2006), this should also be the case for rhyolite domes. Density measure- ments of rock samples have been made for most types of Icelandic rock (Pálsson et al., 1984; Gudmundsson and Högnadóttir, 2004). A knowledge of rock den- sities is necessary for applying the Bouguer anomaly and the Nettleton method (e. g. Kearey et al., 2002). The mean bulk density of the surface bedrock in the Krafla caldera was obtained by Johnsen (1995) by applying the Parasnis method (Parasnis, 1973) to the entire Krafla caldera. In the Bouguer reduction we use his value of 2500 kg m−3 as our background density. The reason is that this density best represents the sur- roundings of the domes, i.e. the bedrock in the Krafla area. A total of 48 gravity stations along nine profiles were measured (Figure 1) over the three dome forma- tions. Observations were carried out in the autumn of 2007 and the spring of 2008, during five days. 138 JÖKULL No. 60

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