Seismic soundings on Skeiðarársandur fellsjökull. Sediment thickness increases towards the sea and bedrock is 200-250 below sea level on the lower part of the sandur (Figure 5). Compared to the upper central part, depth to bedrock is much greater on the eastern part of the sandur, near the bridge over Skeiðará (Figure 4). The two profiles located in its vicinity (SKS2 and SKS3) reveal a depth of 180-210 m. Thus an erosional channel may exist in the eastern part of the sandur. Depth to bedrock decreases again near Svínafellsjök- ull where it is 75 m in front of the glacier terminus. LAYERING OF SEDIMENTS While the interval velocities obtained through the Dix equation are very approximate and subject to consid- erable uncertainty, the determination of distinct layer- ing above bedrock is robust. Moreover, there is a clear pattern of higher velocities in the deeper sedimentary layers. The uppermost layer (V = 1.4-1.8 km s_1) has velocity characteristic of unconsolidated water- saturated fluvial sediments. It is therefore consid- ered to consist of glaciofluvial sediments that have not been subjected to any appreciable compaction. This layer is thin or absent inside the outermost termi- nal moraines of Skeiðarárjökull and Svínafellsjökull. Its thickness increases rapidly outside the moraines reaching over 150 m in vicinity of the Skeiðará bridge and near the coast (Figures 4 and 5). On the basis of sediment grain size, Boothroyd and Nummedal (1978) divided Skeiðarársandur into four areas, with coarseness of sediments gradually de- creasing with increasing distance from Skeiðarárjök- ull. Proximal to the glacier are tills, grading to coarse gravel through to fine gravel, with the lower half of the sandur largely composed of sand-sized material. The velocities recorded in our profiles show little cor- relation with this classification apart from the signifi- cantly higher velocities in the till facies area. The layers underneath the unconsolidated glacio- fluvial sediments have velocities in the range 1.9- 2.7 km s_1 (Figures 4 and 6). The lower values (1.9-2.2 km s_1) may be due to coarse-grained sedi- ments; Flaraldsson and Palm (1980) obtained a good correlation between coarseness and seismic velocity in the Markarfljót sandur. An alternative explana- tion would be that these velocities represent somewhat compacted sediments of the same type as the top layer. On Breiðamerkursandur, Bogadóttir et al. (1987) recorded velocites of 1.5 km s_1 outside the Little Ice Age moraines but 1.9-2.0 km s_1 in the same type of sediments within the moraines. They suggested that the higher velocities arise because of compaction by ice loading. Boulton and Dobbie (1993) presented a model explaining how the flux of groundwater in sed- iments under a glacier may lead to such consolidation. On Skeiðarársandur, the layer with velocity 1.9- 2.2 km s-1 reaches almost to the surface within the Skeiðarárjökull Little Ice Age moraines while the thickness of the overlying unconsolidated sediments increases rapidly outside the moraines. Although in- creased coarseness undoubtedly plays a role in in- creasing seismic velocity in the proximal zone of Skeiðarárjökull, the close correlation between maxi- mum extent of the Little Ice Age moraines and sed- iment velocity suggests that compaction by glacier load is an equally plausible mechanism. At Svína- fellsjökull (Figures 7 and 8) the relationship be- tween seismic velocity and Holocene glacial extent is particularly instructive. The profile HS coincides roughly with the maximum extent of the glacier in the Holocene, the Stóralda stage considered to date back to the onset of climatic deterioration 2500 years BP (Þórarinsson, 1956). This profile has a velocity of 2.2 km s-1 at about 10 m depth while no such layer is found in profile FR, only 0.8 km to the west. The highest velocities found in the Skeiðarársand- ur sediments (2.5-2.7 km s-1) indicate consolidated sedimentary rocks. The fact that the upper surface of this layer shows up as a reflection indicates that it is an unconformity; this lowermost layer may be sedi- mentary rock of Pleistocene age. In profile SKS3 a layer with a velocity of 3.7 km s-1 showed up as a refraction (Figure 4) at about 40 m depth. The origin of this layer is unknown. The ve- locity is unusually high for a sedimentary layer and it seems to be underlain by more than 100 m of uncon- solidated sediments. The likelihood of a buried lava flow at this location is small. This may be a thin fully consolidated layer within the sediments, perhaps due to palagonitization or some other alteration process. JÖKULLNo. 51 59

Síða 1
Síða 2
Síða 3
Síða 4
Síða 5
Síða 6
Síða 7
Síða 8
Síða 9
Síða 10
Síða 11
Síða 12
Síða 13
Síða 14
Síða 15
Síða 16
Síða 17
Síða 18
Síða 19
Síða 20
Síða 21
Síða 22
Síða 23
Síða 24
Síða 25
Síða 26
Síða 27
Síða 28
Síða 29
Síða 30
Síða 31
Síða 32
Síða 33
Síða 34
Síða 35
Síða 36
Síða 37
Síða 38
Síða 39
Síða 40
Síða 41
Síða 42
Síða 43
Síða 44
Síða 45
Síða 46
Síða 47
Síða 48
Síða 49
Síða 50
Síða 51
Síða 52
Síða 53
Síða 54
Síða 55
Síða 56
Síða 57
Síða 58
Síða 59
Síða 60
Síða 61
Síða 62
Síða 63
Síða 64
Síða 65
Síða 66
Síða 67
Síða 68
Síða 69
Síða 70
Síða 71
Síða 72
Síða 73
Síða 74
Síða 75
Síða 76
Síða 77
Síða 78
Síða 79
Síða 80
Síða 81
Síða 82
Síða 83
Síða 84
Síða 85
Síða 86
Síða 87
Síða 88
Síða 89
Síða 90
Síða 91
Síða 92
Síða 93
Síða 94
Síða 95
Síða 96
Síða 97
Síða 98
Síða 99
Síða 100
Síða 101
Síða 102
Síða 103
Síða 104
Síða 105
Síða 106
Síða 107
Síða 108
Síða 109
Síða 110
Síða 111
Síða 112
Síða 113
Síða 114
Síða 115
Síða 116