Agustsdottir et al. geology of Iceland is characterised by the interac- tion of spreading at the mid-ocean plate boundary and the hotspot, centered in east-central Iceland under the Vatnajökull icecap (Wolfe et al., 1997). The diver- gent plate boundary is marked by a chain of active central volcanoes traversing Iceland, resulting from plate rifting and volcanism induced by upwelling of the hotspot. Central volcanoes are defined by fre- quent eruptions from a central area (Walker, 1963; Sæmundsson, 1978). Volcanism in the neovolcanic zone results in elongated volcanic systems, consisting of a central volcano and a transecting fissure swarm (Sæmundsson, 1978, 1979). A geothermal field is often associated with the central volcano. Further- more, silicic rocks in Iceland are generally associ- ated with central volcanoes (Jónasson, 2007) and most central volcanoes have only produced minor amounts of silicic rock in a few formations (Jóhannesson and Sæmundsson, 1999). No dome eruption has been observed with modern monitoring equipment in Ice- land while the geological record contains many silicic tephra layers, lavas and dome formations (Jóhannes- son and Sæmundsson, 1999; Larsen, 2000). Domes in Iceland generally occur at or near the caldera rims of an active central volcano. The sides of the underlying magma chamber are thought to represent the best con- ditions for the formation of silicic melts due to cool- ing of the hydrothermal system (Jónasson, 1994). The central volcano Krafla, situated in the NVZ (Northern Volcanic Zone), has an ice-free caldera surrounded by subglacially formed silicic domes Hlíðarfjall, Hrafn- tinnuhryggur, Jörundur and Rani (not studied here), all located close to the caldera rim. (Sæmundsson, 1991). The Krafla area is both easily accessible and one of the most intensely studied volcanic areas in northern Iceland, due to the geothermal power plant situated above the caldera’s shallow magma chamber and the recent volcano-tectonic episode, the Krafla fires, in 1975–1984 (e.g. Einarsson, 1991; Buck et al., 2006). For these reasons the Krafla region was cho- sen as a study area to examine Icelandic domes in an active central volcano. The determination of the vent structure can shed light on how these domes were em- placed, e.g. whether they were formed by a dike-fed eruption or by a more forceful emplacement displac- ing surrounding strata in the process. Buoyancy is important in driving magma through the crust, and therefore density data are necessary for meaningful modelling of the emplacement of cryptodomes and lava domes. The aim of the present work was there- fore to determine poorly known bulk density values for domes and to investigate whether the domes have roots. Rock samples were also collected and their density measured to further constrain the results. GEOLOGICAL SETTINGS The Krafla volcanic system The Krafla volcanic system (Figure 1) is located in the Northern Volcanic Zone (NVZ). The NVZ consists of several elongated closely spaced volcanic systems, amongst which the Krafla and Askja volcanic systems are most active. The Krafla volcanic system consists of a central volcano and a transecting fissure swarm. The Krafla caldera is approximately 10 km wide, tran- sected by a 100 km long and N10◦E trending fis- sure swarm (Sæmundsson, 1991). Around the caldera a number of concentric fissures have erupted hyalo- clastites, lavas and rhyolite (Sæmundsson, 1991). A powerful geothermal system lies inside the caldera, harnessed by a geothermal power station operated since 1977. The Krafla caldera began forming about 100 000 years BP (Sæmundsson, 1991). Due to the in- tensive volcanism, stratigraphic build up has been rel- atively fast, both during periods of ice-free conditions and periods when ice covered the land. In the geologi- cal strata of the Krafla caldera there is evidence of two main warm periods. The silicic rocks are concentrated around the caldera rim and away from the central part of the fissure swarm (Sæmundsson, 1991). The Heiðarsporður volcanic system Heiðarsporður is a small volcanic system located south of Krafla. Its topographic expression is a low and broad ridge, about 15 km long and 3 km wide, extending from the Krafla central volcano in the north towards the Bláfjall ridge and in the south to the Fremrinámur central volcano. This volcanic system was active for a relatively short time (1000 years) in the early Holocene and was built up in several small 136 JÖKULL No. 60

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