phy suggest that there were at least two glaciations in each area within the Gauss epoch. Paleomagnetic measurements made on 10 samples from three differ- ent locations within diamictite unit 7 (glacial deposit 3) in Borgarfjörður, however, gave reversed polarity in contrast to normal polarities of both under- and over- lying lavaflows in all sections (Figs. 5 and 8) (Geirs- dóttir, 1988). These paleomagnetic results from the diamictites in Borgarfjörður are scattered, but the po- larity signal is consistent indicating a reversed event during their formation. However, before question- ing the previously assumed stratigraphic position of the diamictites within the Gauss magnetic epoch, fur- ther investigation of the reliability of the paleomag- netic signals within diamictites is necessary. The two stratigraphically youngest glacial deposits in Borgar- fjörður and the four stratigraphically youngest glacial deposits in Hvalfjörður fall within the upper part of the Matuyama polarity epoch (Fig. 8) (McDougall et al., 1977; Kristjánssoneí al., 1980; Geirsdóttir, 1988). Indications of changes in the style of glacial ac- tivity from the first identified glacial unit to the last, in both the upper Borgarfjörður area and the Hval- fjörður area, appear mostly in the regional extent of hyaloclastites. In Borgarfjörður, hyaloclastites are ini- tially restricted to the volcanic center and only later spread out over most of the southem part of the up- per Borgarfjörður area. This may indicate that the oldest glacial deposit was formed by a valley glacier that extended from a small ice cap covering the active and growing volcano. There is, however, no evidence of valley erosion at this stratigraphic level in Borgar- fjörður and the stratigraphy points to a rather low relief apart from the growing volcano. But the clast fabric measurement from this first glacial deposit shows a very consistent orientation of the particle long axes, a NNE-SSW orientation, whereas all the other strati- graphically younger glacial deposits show an orienta- tion directed N-S or NNW-SSE. The second glacial deposit (diamictite 6) in Borgarfjörður section was deposited subglacially and shows features related to both lodgement and melt-out of debris from ice. This glacial unit shows a strong unimodal fabric pattern oriented NNW-SSE at all site locations. This is also valid for the third glacial deposit (diamictite 7), apart from the westemmost site location at Valagil, where particle long axes are oriented more toward N-S. This third glacial deposit resembles basal melt-out tillite. It is, however, in places less well preserved than the un- derlying glacial units, but in other places it is followed by glaciofluvial and thick lake deposit (Asgil). This may be attributed to more effective fluvial erosion associated with the retreat of the glacier or possibly lessened volcanic activity within the central volcano which promoted erosion rather than burial by contin- ued eruptions. Neither the second or the third glacial unit are directly associated with hyaloclastites except within the volcanic center. The next diamictite unit (diamictite 8) which is separated from the underlying sedimentary deposit by olivine tholeiite lava flows, is only found in one gully as a thin debris bed. A 100 metre thick hyaloclastite pile located within the central volcano is correlated with this sediment (Sæmundsson andNoll, 1974). Hence, itmay indicatetheeruptionof an ice-capped volcano and thus reflect local deposition rather than a major glacial activity. Hyaloclastite as- sociated with the oldest tillite of the area is restricted to the volcanic center, whereas the youngest tillites in the area are directly overlain by tuffaceous hyalo- clastites. Thick glaciolacustrine deposits or tuffaceous hyaloclastites are preserved with the stratigraphically younger glacial deposits but these are minor or absent from the two oldest tillites. Fragmentation of extruded lavas as overlying ice melted and the formation of avalanches of hyalo- clastite sheets may explain how some diamictite units became intercalated with basalts and hyaloclastites in the Hvalfjörður stratigraphy. Clast fabric measure- ments made on glacial deposits in the Hvalfjörður area all show southeasterly to northwesterly orienta- tion. These glacial deposits become thicker towards east, whereas diamictite units 2 and 3, become thicker towards west and show an orientation perpendicular to the prevalent orientation. These deposits, units 2 and 3 have been attributed to mass flow and fluvial deposition. The Hvalfjörður section resembles the Borgarfjörður section in containing thick glaciolacus- trine deposits or tuffaceous hyaloclastites in associa- tion with the stratigraphically younger deposits, but these are not as extensive facies associations with the 20 JÖKULL, No. 40, 1990

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