Paleomagnetic studies in Skarðsheiði, South–Western Iceland Leó Kristjánsson Science Institute, University of Iceland, Dunhaga 3, 107 Reykjavík Ágúst Guðmundsson ÁGVST Geological Services, Ármúla 4, 108 Reykjavík Abstract – We have mapped a well–exposed composite profile through the lava pile in the western part of the Skarðsheiði mountain, and made detailed laboratory measurements of paleomagnetic remanence directions in oriented samples from 92 lava sites from this profile. The lower 55 lavas or so consist of a partially recorded normal–polarity zone, overlain by a thick reverse–polarity zone. The latter which includes a series of por- phyritic lavas, was named R5 by Einarsson (1957). The upper part of our profile contains a normal–polarity sequence of about 20 flows (N5 of Einarsson) and a partially recorded reverse zone. Franzson (1978) and others have correlated the R5–N5 boundary with a similar boundary in the Akrafjall mountain and with the transition between the Gilbert and Gauss geomagnetic chrons. We have also sampled 29 lavas in two shorter profiles farther east in Skarðsheiði, at the boundary between the R5 and N5 polarity zones. We confirm the observation of Wilson et al. (1972) and Kristjánsson and Sigurgeirsson (1993) that several lava flows with transitional directions occur at this boundary at the northern side of the mountain. Only a few such flows are found on the south slopes of Skarðsheiði. At least three short geomagnetic excursions are recorded in the R5 zone. The lava flows are good material for paleomagnetic direction measurements, although hydrothermal alteration has affected the lowest part of the composite profile. Their average direction is quite similar to the axial dipole field as expected. Thermomagnetic tests on several samples indicate that they are not very suitable for paleointensity studies. INTRODUCTION Geology The thick sequences of subaerial lava flows (mostly of basalt) and minor sediments, which are exposed above sea level in Iceland, are generally thought to have been erupted in an active zone of rifting and vol- canism. This zone which belongs to the Mid–Atlantic rift system, trends roughly from south–west to north– east through the island (Figure 1; see review by Sæ- mundsson, 1986). The rift activity in the southwest has been suggested to have moved to a new location some tens of km to the east about 15 M.y. ago (Harðar- son et al., 1997) and again 5–7 M.y. ago, with a third ridge jump being in progress in the Late Quaternary. Eruptive activity at any time is mostly confined to central–volcano complexes within the volcanic zones. The zones of volcanism are constantly subsiding as a result of the extrusive volcanism, so that the exposed lava pile tilts towards them (Walker, 1959, 1965). In South–Western Iceland this regional dip is of the or- der of 5–10 degrees to the south–east, decreasing up- wards; considerable local variations in dip occur, es- pecially near the central volcanoes. Some regional hy- drothermal alteration has occurred in the lava pile, in- creasing with depth. In the Akrafjall mountain (Figure 1) for instance, an alteration zone characterized by the zeolites mesolite and scolecite is apparent from sea level and up to about 100 m elevation, where it is fol- lowed by an analcime zone, a chabazite–thomsonite zone and then from 500 m altitude to the top at 550 m JÖKULL No. 50 33

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