Foulger and Field cube. These velocities were used to calculate a density for each cube. The expression for the gravitational ef- fect of a rectangular parallelepiped (Talwani, 1973) was used to calculate the effect of each cube at the surface and the effects of all the cubes were summed to give the simulated Bouguer anomaly fields. The observed Bouguer anomaly fields were calculated from the original gravity measurements. The Parasnis method was applied to estimate a Bouguer reduction density for each area. This met- hod is described in detail by Parasnis (1962) and in- volves rearranging the Bouguer anomaly equation to express gravity at the stations as a function of heig- ht and density and the Bouguer anomalies as random errors. , APPLICATION TO THE HENGILL-GRENSDALUR AREA A bulk rock density of 2,400 kg/m3 was obtained using the Parasnis method. This compares with a Bouguer reduction density of 2,600 kg/m3 used by Þorbergsson et al. (1984). Laboratory measurements of the wet densities of 15 rock specimens from the Hengill-Grensdalur area were also available. The specimens were collected from Nesjahraun, a post- glacial lava flow NE of Hengill, and from hyalocl- astite units within the Hrómundartindur system and the Grensdalur central volcano. Large samples were split into 5 or 6 blocks 6-10 cm3 in volume and individual determinations made for each. The wet densities of the samples vary from 2,110 to 2,800 kg/m3 and the porosities lie in the range 8-40%. The results illustrate the large variation in the physical properties of the near-surface rocks. The average wet density of the whole suite is 2,465 ± 100 kg/m3. On the basis of all the information available, a Bougu- er density of 2,450 kg/m3 was used to calculate the observed Bouguer anomaly field (Figure 5). A NE-SW regional gradient of approxiamtely 20 mGal occurs over the area. This was removed us- ing the quadratic surface which minimises the RMS gravity residual, and a constant was added to all the Bouguer anomaly values so the field had a mean value of zero (Figure 6a). The observed and simulated Bouguer anomaly fields (Figures 6a,b) may only be compared in a relati- ve sense since the datum of each is arbitrary. Bearing this in mind it may be seen that the simulated gra- vity field bears considerable similarity both spatially and in amplitude to the observed field. Positive anom- alies occur of about 1-2 mGal at (2,13) over Húsmúli and 3-4 mGal at about (8,6) in the Grensdalur area. The Bouguer lows south and north of Hengill and over Hrómundartindur in the observed field are, on the ot- her hand, absent in the simulated field. The simulated Bouguer anomaly field was su- btracted from the observed field and the residual is illustrated in Figure 6c. The residual field contains fewer and smaller anomalies than the real field. The most serious discrepancies occur south of Hengill (at about 1,10) and at Hrómundartindur (12,7). The RMS anomaly for the real field is 2.05 mGal compared with 1.81 mGal for the residual field. In order to assess how much of the significant Bouguer anomaly field is unexplained by the LET model, an error budget was made. The most serious uncertainties arise from 6 sources: 1. the values of measured gravity, 2. the density used to make the Bouguer and terrain corrections (the Bouguer density), 3. the LET velocity model, 4. variations in the density above sea level, 5. variation in the velocity : density relationship for rocks below sea level, and 6. errors in detrending the Bouguer gravity field. Errors in the values of gravity are estimated by Þorbergsson et al. (1984) to be occasionally up to about 0.5 mGal. The error in the LET velocity model was conservatively assumed to be about 0.1 km/s, alt- hough repeat LET indicates that it may be still higher. The error in the Bouguer density used for the whole area was assumed to be 100 kg/m3, a figure that is again conservative compared with the variation in Bouguer densities used by other authors (e.g., Þor- bergsson et al. 1984; Hersir et al. 1990). Quantifying the errors from the last three sources is not straight- forward. In particular, the density of the material abo- ve sea level is known to vary over the area (Hersir et al. 1990). 38 JÖKULLNo. 48

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