Surface and bedrock topography of Mýrdalsjökull proportional to the velocity of the receiver sledge, measured with a bicycle wheel odometer. The velocity of electromagnetic waves in ice was assumed to be 169 m/ . s. This same value was also used for the surface firn layer, as its maximum thickness is on- ly about 20-30 m. The vertical thickness of the ice was computed from a digitized sounding record using general inversion techniques as described by Harri- son (1970). The sounder sees a strip along the bed of width typically 100-200 m (defined by the first Fresnel zone for a pulse length of 34 m, Björnsson, 1988). Along each sounding line the recorded data represents a moving average of the real bed profile on a strip beneath the line. The accuracy of the absolu- te ice-thickness measured along the sounding lines is considered to be , 15 m or 2%, whichever is greater. Echo returns were obtained over the whole glacier, however, they were faint in some places adjacent to and south of the northeastern caldera rim, Austmanns- bunga, where the ice thickness reaches 600-680 m. Data from Mackintosh et al. (2000) were used to compile the map of the Sólheimajökull outlet glacier. The bedrock elevation was obtained as the difference between the ice surface altitude and the ice thickness. Map compilation Digital elevation maps (DEM) of the bedrock and surface topography, with equal grid spacing of 100x100 m, were compiled by interpolating data from our soundings and existing geodetic maps of the area surrounding the ice cap. Outside the surveyed area, the final glacier surface map is based on the DMA-series of the Iceland Geodetic Survey (1990). The residual between elevations on our survey lines and the DMA-map was calculated and a new map produced by adding the calculated residuals to the DMA-map. The outlines of the glaciers are the same as on the DMA-series. Due to the large spacing between the sounding lines (typically 500-1000 m), the topographic map does not fully reproduce features smaller than 1-2 km across, but local detail is described along the sounding lines. However, relative resolution of the bedrock data with respect to topographical features is considera- bly better. Volcanic and tectonic structures of vertical extension of the order of 10 m and larger can thus be resolved, e. g. hyaloclastite ridges and major normal faults but we are unable to delineate fissure zones with small vertical displacements. The maps are presented in conformal conical Lambert-coordinates with coordinate axes originating at 65 / N and 18 / W. The rows and columns in the matrix implicitly define the geographic coordinates. Smoothed contour maps were drawn from the digital matrix. The glacier surface map The central parts of the ice cap form a plateau at an elevation of about 1,300 m (Figures 3 and 4), surrounded by higher rims at Háabunga (1497 m) and Goðabunga (1505 m), the nunatak Austmanns- bunga (1377 m) and Kötlukollar (1320 m). This is the surface expression of the Mýrdalsjökull caldera. Steep outlet glaciers flow in narrow valleys down to 100-800 m on the southern and western flanks. Broader outlets drain eastward down to 200-400 m, and one large ice lobe covers the northern flank down to 600-650 m. The surface map shows 12 small depressions in the glacier surface that have been created by su- bglacial geothermal activity. These ice cauldrons are typically 20 to 50 m deep and their diameter is 500 to 1000 m. The most striking difference between our map and the 1938 map of the Danish Geodetic Institute is that we describe the sharp elongated shape of the ridges Háabunga and Goðabunga. At Háabunga the elevati- on of the old maps was wrong by up to 200 m, mainly due to misplacement of the dome. In contrast our map is very similar to that compiled by Sigurðsson in the 1940s (Rist, 1967a). Bedrock terrain and geological structures The most prominent landform beneath the ice cap is a large volcano with a circular base of a 20 km dia- meter at 700 m elevation and 30-35 km at the base. The mountain rises up to rims of 1300-1380 m that surround a 650-750 m deep caldera, reaching down to an elevation of about 650 m (Figures 5, 6 and 7). The area of the depression, girded by the highest points on the rim, is 100 km . The arcuate ridges reaching about 1300 m elevation, form the caldera rims beneath Háa- bunga, Goðabunga, and between Enta and the nuna- JÖKULL No. 49 33

Qupperneq 1
Qupperneq 2
Qupperneq 3
Qupperneq 4
Qupperneq 5
Qupperneq 6
Qupperneq 7
Qupperneq 8
Qupperneq 9
Qupperneq 10
Qupperneq 11
Qupperneq 12
Qupperneq 13
Qupperneq 14
Qupperneq 15
Qupperneq 16
Qupperneq 17
Qupperneq 18
Qupperneq 19
Qupperneq 20
Qupperneq 21
Qupperneq 22
Qupperneq 23
Qupperneq 24
Qupperneq 25
Qupperneq 26
Qupperneq 27
Qupperneq 28
Qupperneq 29
Qupperneq 30
Qupperneq 31
Qupperneq 32
Qupperneq 33
Qupperneq 34
Qupperneq 35
Qupperneq 36
Qupperneq 37
Qupperneq 38
Qupperneq 39
Qupperneq 40
Qupperneq 41
Qupperneq 42
Qupperneq 43
Qupperneq 44
Qupperneq 45
Qupperneq 46
Qupperneq 47
Qupperneq 48
Qupperneq 49
Qupperneq 50
Qupperneq 51
Qupperneq 52
Qupperneq 53
Qupperneq 54
Qupperneq 55
Qupperneq 56
Qupperneq 57
Qupperneq 58
Qupperneq 59
Qupperneq 60
Qupperneq 61
Qupperneq 62
Qupperneq 63
Qupperneq 64
Qupperneq 65
Qupperneq 66
Qupperneq 67
Qupperneq 68
Qupperneq 69
Qupperneq 70
Qupperneq 71
Qupperneq 72
Qupperneq 73
Qupperneq 74
Qupperneq 75
Qupperneq 76
Qupperneq 77
Qupperneq 78
Qupperneq 79
Qupperneq 80
Qupperneq 81
Qupperneq 82
Qupperneq 83
Qupperneq 84
Qupperneq 85
Qupperneq 86
Qupperneq 87
Qupperneq 88
Qupperneq 89
Qupperneq 90
Qupperneq 91
Qupperneq 92
Qupperneq 93
Qupperneq 94
Qupperneq 95
Qupperneq 96
Qupperneq 97
Qupperneq 98
Qupperneq 99
Qupperneq 100
Qupperneq 101
Qupperneq 102
Qupperneq 103
Qupperneq 104
Qupperneq 105
Qupperneq 106