same period palaeomagnetic mapping of lava groups was first applied on a regional scale by T. Einarsson in western Iceland, a decade before the polarity time scale was established. Systematic mapping on a regional scale has been carried out in.most parts of the Tertiary areas, but is far from complete. The longest continuous sec- tion studied so far is in eastern Iceland, and in- volves an 8.5 km thick lava succession composed of some 700 individual lava flows. This is not a true vertical thickness because of successive offlapping of younger flows as the growing lava pile was transported sideways (Fig. 2). The section spans a time interval of over 10 m.y. from about 13.4 m.y. up to the Plio-Pleistocene. The build up rates taken at face value uncorrected for down dip thickening are variable by a factor of seven. The lowest 4 km were extruded at an average rate of 720 m/m.y. The next 3.0 km at 2600 m/m.y., and the upper- most 1.5 km at rate of only 360 m/m.y. The lowest build up rate was found for the period from about 6.5 m.y. up to the top of the section. On strike to the north rocks representing this time interval are partly lacking and a hiatus is present. In northern Iceland a 5 km section with an age range of about 3 m.y. (beginning at about 12 m.y. and ending at 9 m.y.) yields a build up rate of about 1000 m/m.y. for the lowest 2.5 km, but an excessive rate of 4000 m/m.y. for the upper 2.5 km of the section. A 3.5 km section in western Iceland rang- ing in age from about 6.5 m.y. up to 2 m.y. was formed at a more or less constant growth rate of about 780 m/m.y. The down dip thickening of the lava groups suggests that generally higher eruption rates would be obtained within the hidden part of the lava pile. A ~ 2 km continuous core obtained in 1978 from a borehole in eastern Iceland may soon give infor- mation about this. The sections on which these values were ob- tained avoided central volcanoes because of associ- ated structural and stratigraphic complexities. During their active periods they are known to pro- duce an excessive thickness of flows so that they stand apart topographically, later to become gra- dually buried by onlapping lavas from younger volcanic systems. Sometimes a period of erosion and considerable sediment accumulation seems to have followed the extinction of the volcanic systems. Prominent sedi- ment horizons that occur in western Iceland and are traceable over tens of kilometers along strike Fig. 5. Northwest Peninsula of Iceland. The trace of major sedimentary horizons mapped to date is shown. Most of these horizons include several sedimentary layers. (Fig. 5) appear to have formed during such tran- sition periods. The sediments are of terrestrial origin, fluvial or lacustrine, with occasional lignite and plant impressions in the more fine grained strata. The palaeobotanical record is more or less continuous for the last 16 m.y. providing a unique opportunity to study climatic trends of the North- Atlantic region over this period (see chapter 6). The most common type of interbeds in the Ter- tiary series are thin layers of red or redbrown clayey or tuffaceous material consisting of an iron stained opaque groundmass and glass in various stages of alteration. The origin of these interbeds is thought to be aeolian, i.e. wind blown ash that has suffered chemical weathering towards laterite. Deep weathering of the underlying substratum is rarely seen; however, this is likely to have occurred at the base of the lowest thick lignite/sediment horizon of the Northwest Peninsula (Botn-horizon of Fig. 5). There the underlying porphyritic basalt has been altered to clay (montmorillonite and kaolinite). In southeastern Iceland ice sheets developed locally in the Pliocene under conditions perhaps similar to the present Vatnajökull area, i.e. high ground and high precipitation. Deposits of glacial origin are found there interspersed within the lava pile back to about 5 m.y. A thick sequence of pre- dominantly marine Pliocene sediment is exposed along the west coast of the Tjörnes Peninsula in northern Iceland amounting to some 500 m in aggregate thickness (Fig. 8). The underlying basalt sequence is at least 9—10 m.y. old, dipping steeply JÖKULL 29. ÁR 11

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
Qupperneq 107
Qupperneq 108