to the north caldera. The subglacial lake covers the greater part of the main caldera and at high water level it has in the past extended into the north cal- dera. The area covered by the lake is the area where geothermal activity is most intense. Surveys aimed at mapping the subglacial topogra- phy in the Grímsvötn area date back to 1951, with the seismic work of the French-Icelandic expedition (Eyþórsson, 1951, 1952; Joset and Holtzscherer, 1954). More seismic reflection work was done in 1955 by the Icelandic-French expedition (Þórarins- son, 1965). However, these surveys failed to provide satisfactory estimates of the elevation of the bottom of the subglacial lake. Gravity surveys were carried out in 1960 and 1961 to obtain more information on the subglacial topography of the area (Pálmason, 1964; Sigurðsson, 1970), but interpretation of the gravity data was difficult due to lack of control points where ice thickness was known and Bouguer anomaly could be determined. Since 1977, the subglacial topography of large parts of the Vatnajökull ice cap has been defined in considerable detail by radio-echo soundings (Bjömsson, 1986, 1988). One part of this work was a detailed survey of the Grímsvötn area, carried out at the same time as the seismic survey. However, as radio waves of the frequency used in the soundings (1 -5 MHz) do not penetrate water, other methods were needed in order to obtain information on the caldera floor beneath the lake. The seismic reflection survey described in this paper complemented the radio-echo soundings by obtaining information on the subglacial lake and the main caldera in Grímsvötn. The survey objectives can be listed as follows: 1. To determine the elevation and topography of the floor of the main caldera in Grímsvötn in as much detail as possible. 2. To measure the area and the volume of the subgla- cial lake and in that way obtain data for the assessment of the flood potential of the area. 3. To obtain information on the structure of the cal- dera, in particular whether it is composed of several smaller calderas. 4. To obtain information on the material deposited on the lakefloor by volcanic eruptions and sedi- mentation, i.e. the caldera infill. In this paper the fieldwork and processing of the data are described and the results of the survey are presented. FIELD PROCEDURES Three seismic reflection lines were surveyed, using a method giving continuous single-fold cover- age. Line 1 (4800 m) bears east-west and line 2 and 3 run north-south (2520 m and 3000 m). The ends of the lines reach some distance on to the slopes that border the ice shelf to north, east and southwest (Fig. 2). The source-receiver arrangement used was. in essence a split spread. However, two shots were fired in each shothole, one for each part of the spread, as all the geophones were placed to one side of the hole for the first shot and then moved to the other side for the second shot. The length of the receiving spread was 230 m, the 12 geophones being placed at 20 m intervals with a minimum offset of 10 m. The second geophone spread for each shothole was used as the first spread for the next shothole on the line (Fig. 3). A single vertical (P-wave) geophone with a natural frequency of 8 Hz was used for each chan- nel. During the course of the survey the weather was sunny and hot, giving rise to wet and slushy snow conditions on the surface of the glacier. Plac- ing the geophones at about 30 cm depth in the snow seemed to give satisfactory coupling. Small dynamite charges (150-400 g) were used as seismic sources. The charges were detonated at the bottom of 30 m deep holes, drilled by a hot water drill. The seismic recording system used was a 12 chan- nel Geometrics Nimbus 1210F. A 80 Hz highpass analog filter on the Nimbus was used for all record- ings apart from the first two shotpoints where a 50 Hz highpass was used. 'Tests showed that the application of the filter produced sharper reflections and improved signal to noise ratio. Each record was 1024 ms long with a sampling interval of 1 ms. JÖKULL, No. 39, 1989 3

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