Several boreholes have been drilled in recent years throughout this area, the deepest of which are in Midfell (347 m) and lilesastadir (270 m). Cuttings from these boreholes and also cores from a 100 m deep borehole near Kaldárholt were examined for secondary minerals. Chaba- zite and tliomsonite are still by far the most abundant secondary minerals in all the bore- holes followed by some scolecite, stilbite and some calcite. The restricted assemblage of secondary min- erals found in the Hreppar Series and the low intensity of zeolitization corresponcls well to the lower half of the chabazite-lhomsonite zone of Walker (1960) established for Eastern Iceland. In rocks of the Hreppar Series anal- cite, the index mineral of the zeolite zone next below the chabazite-thomsonite zone, was neith- er found in the exposed rocks nor in the bore- hole cuttings. The highest level at which zeo- lites were found is in Berghylsfjall at 250 m altitude on the northern border of the map (Fig. 2). Here a group o£ olivine basalts con- tains abundant chabazite, besides some thom- sonite and opal. The top of the chabazite- thomsonite zone thus must lie higher than this and the top of the lava pile may originally have been several 100 m higher. Walker and Charmichael (1962) assume a combined thick- ness of 800—1000 m for the chabazite-thom- sonite zone and a pile of rocks void of second- ary minerals on top of it. According to this in Hreppar a considerable thickness of rocks pos- sibly some 500—700 m has been eroded before the outpouring of the interglacial lavas. As compared to Eastern Iceland, however, several factors complicate the reconstruction of secondary mineral zoning and the determinat- ion of the top level of the succession. Most significant are probably abundant hyaloclastites within the Hreppar Series, since basaltic glass is particularly liable to devitri- fication and zeolitization. The Hreppar Series is of relatively young age, but it has neverthe- less been strongly tilted and eroded. It is pos- sible that the geoisotherms reached their high- est level only subsequent to the deepest burial of the Hreppar Series. In other words the process of zeolitization may have been inter- rupted by rapid erosion. The present day high geothermal gradient and widespread hydro- 66 JÖKULL 20. ÁR thermal activity of the lowlands of Southern Iceland probably is the surface expression of the process of zeolitization still taking place at depth in this region. FAULTING The area described here has been much af- fected by faulting that lias continued into post- glacial time. The most common trend of faults is N 15°—30° E. These are normal faults some of which have a downthrow of several tens of meters ancl they are arranged in a step fault pattern with downthrow to the east towards the axis of the Hreppar anticline. Strike slip faults exist in Vördufell trending N 10—25° E and probably also in Midfell ancl south of Hruni, trending N 50—60° E. In Vördufell strike slip movement of about 6 m with right lateral movement was measured in one case, where several dykes had been moved apart along a fault trending N 20° E. This fault forms the continuation of a fissure swarm mentioned by Tr. Einarsson (1967) and inter- preted by him as indicating strike slip move- ment of the same sense as the fault in Vördu- fell. Faults are sometimes seen to cut through the young lavas. In Skardsfjall a fault trending N 60° E evidently is present and another with the same trend occurs in Háholtsfjall. To the south of Thjórsá, the only faults were found along the course of Steinslaekur trending N 30° E, and north of Holtsmúli, trending N 15° E. To the west of Thjórsá open fissures occur in the districts Skeid and Hraungerdis- hreppur in postglacial lava where conditions are favourable for their preservation. These are the only recent faults observed. DISTRIBUTION OF THE INTERGLACIAL LAVA FLOWS With a sharp unconformity (Fig. 3) the tilted basement of the Hreppar Series is overlain by extremely fresh looking but strongly eroded liorizontal lava flows. These young lavas extend over an area of nearly 250 km2 mainly between the rivers Thjórsá and Rangá (Fig. 1). The easternmost occurrence is along the river bed of Rangá from Geldingalaekur down to Aegisídu- foss. East of Rangá extensive river deposits

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