greatest chemical diversity (Sigvaldason et al., 1974). Seismic evidence supports the hypothesis that this area is underlain by the central part of a mantle plume of low velocity material (Tryggvason et al., 1983; Ge- brande et al., 1980). This section of the neovolcanic zone is largely covered by the ice cap Vatnajökull (Fig. 1), and therefore its geological structure is only poorly known. The area has been volcanically active in historical times and early seismic work revealed it as one of the most seismically active areas in Iceland (Tryggvason et al., 1958; Tryggvason, 1973). Erup- tions have led to tephra fall and floods of meltwater, often damaging vegetation, farms and roads in coastal areas. Because of their remoteness and glacial cover, the location of many eruptions is uncertain. Many have been ascribed to the well known Grímsvötn vol- cano, but the wide distribution of epicentres in the area and recent attempts to relocate eruption sites from bearings taken to the eruption plumes indicate that the active area is considerably larger (Þórarinsson, 1974). New insight into the geological structure was gained when satellite images of Vatnajökull became available (Þórarinsson et ai, 1973). In some areas, the subglacial bedrock topography is reflected in the surface forms of the ice. A caldera was seen to ex- ist beneath the ice cover of Bárðarbunga,which was thus identified as an active volcano. Caldera struc- tures were also seen in other volcanoes such as Kverk- fjöll, Grímsvötn and Tungnafellsjökull (Fig. 2). It be- came evident that the geological structure of the area is dominated by several large central volcanoes. Fissure swarms outside the ice cap have been traced to the glacier edge (Sæmundsson, 1978, 1980; Jakobsson, 1979, 1980), but so far it has been unclear how these are connected with central volcanoes beneath the ice to form extensive volcanic systems. The term ”vol- canic system“ was originally introduced by Jakobsson (1979) to cover both the term central volcano and its associated fissure swarm. One may define a vol- canic system as a spatial grouping of eruption sites with particular tectonic, petrographic and geochemi- cal characteristics. In some volcanic systems the fis- sure swarm is the most prominent structure, in others the central volcano is well developed, sometimes with a caldera, extensive acidic volcanism and geothermal activity. A volcanic system may contain more than one central volcano (e.g. Hofsjökull- Kerlingarfjöll) and fissure swarms sometimes branch into two or more subswarms. One may therefore easily get into prob- lems with the definition of individual systems. During the past ten years, the bedrock topography beneath the ice has been mapped extensively using radio echo sounding (Björnsson, 1988; Bjömsson, in prep.). At the same time increased seismograph coverage has led to more precise epicentral locations (Einarsson and Bjömsson, 1987; Einarsson, 1991)- This information has added significantly to the under- standing of the geology of the area beneath Vatnajök- ull. Seismic activity in conjunction with topographic highs reveals active volcanoes. Ridges, presumably built up by subglacial fissure eruptions, show the lo- cation of fissure swarms. The purpose of the present paper is to integrate this recently acquired knowledge of the subglacial volcanic regions in Vatnajökull. The volcanic systems in the area are delineated and the paths of meltwater produced in eruptions are traced to the various rivers draining the glacier. Information on historical eruptive activity is reconsidered in the light of this evidence. MAPPING OF BEDROCK TOPOGRAPHY AND SEISMIC ACTIVITY BEDROCK TOPOGRAPHY The topographical maps of Vatnajökull (Figs. 3 and 4) are based on continuous ice-thickness profil- ing by radio echo-sounding and precision barometric altimetry (see Bjömsson, 1988). The maps were con- structed by interpolation between sounding lines using a digital matrix with a grid spacing of 200 x 200 m. Due to the large spacing between the sounding lines (typically 1000 m), the topographic maps do not usu- ally represent features smaller than some kilometres across. The accuracy of the absolute ice-thickness measurements along the sounding lines is of the order of ± 15 m, and the accuracy of the measurements of absolute ice-surface elevation is of the order of ± 10 m. Relative resolution of the data with respect to to- pographical features is considerably better than this, however. Volcanic and tectonic structures of the order 150 JÖKULL, No. 40, 1990

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