pebbles of a very uniform size. All pebbles are very vesicular and are evenly distributed throughout the sediment. Except for a polished pavement beneath the diamictite, these are features that argue against a direct glacial deposition for the sediment. The boulder bed at the bottom within the layered lowermost one metre suggests traction at the base and the nearly uniform dispersion of clasts through the thickness of the oth- erwise structureless fine matrix is probably the result of dispersive pressure between the colliding particles. These are conditions indicative of rapidly deposited debris flow or surge type deposit. The principal vec- tor direction from both pebble and magnetic fabric measurements is transverse to the inferred orientation of lineations of the polished surface of the underly- ing basalt, and parallel to the strike direction of the diamictite unit. This fabric pattem is comparable to a fabric pattem found for Mt.St. Helens debris flows (Mills, 1984; Major and Voight, 1986). Based on similar stratigraphic position, Sæmundsson and Noll (1974) correlate this diamictite with ill sorted and in places clast supported sediment that crops out at Hvít- ársíða. However, the Giljafoss section has very differ- ent attributes in comparison to the correlative section m Hvítársíða which suggests two different, but local source areas. Fabric pattem derived from the Hvít- ársíða section is dispersed and shows low significant values (s \) similar to the debris flow samples from the volcano Hekla in Iceland (Geirsdóttir, 1988). The second diamictite unit is separated from the first one by a 120 m thick lava sequence. It con- tains thin massive tuffaceous beds intercalated with faintly bedded conglomerate capped with trough cross bedded tuffaceous sandstone. In thin section, this sediment is almost entirely made up of glass frag- ments (fresh sideromelane glass) with very few rock or mineral fragments in the matrix. It shows less lat- eral extent than most other sedimentary horizons in the area and considerably less variation in composi- tion. Its existence is attributedto flood-flow processes mainly because of the lack of bedforms, followed by fluvial activity which promoted the bedding and cross- stratification in the upper part of the unit. Between the second unit and diamictite unit 3 is a 110 m thick succession of basalts, dacite, ign- imbrite and andesite (Sæmundsson and Noll, 1974). The acidic affinity of the eruptional phase is clearly imprinted on the third diamictite unit. It is in places made up of light coloured lenticular pumice fragments. In some locations this deposit has many similarities in field appearance to the floodflow deposit of the sec- ond diamictite unit except it is much more volumi- nous, in places coarser grained and has greater lateral facies variability. Furthermore, it is intercalated with lava flows which suggests a continuing and concurrent volcanic activity and sedimentary deposition. The five glacial deposits found in the upper Borg- arfjörður section have a distinctly different structure, texture, and more heterogeneous lithology than the other sedimentary units within the area. The oldest identified glacigenic sediment in the upper Borgar- fjörður (diamictite unit 4) preserves fissility and shear features and boulder pavement indicative of lodge- ment and basal melt-out of debris from ice. The eastemmost section of the same diamictite unit (in Deildargil) is also associated with channelized fluvial deposits (Figs. 2 & 6a). In most cases both pebble fabric and remanent magnetic measurements show a unimodal pattem which is thought to be diagnostic of both melt-out and flow mechanisms, but in a few a bimodal pattem occurs, probably indicating glacial marginal deposition and shearing of basal till. This fourth diamictite unit is also the oldest unit in the area that is associated with hyaloclastite formation within the volcanic center (Fig. 2). Approximately 50 m of basaltic and acidic rocks separate the oldest glacial deposit from the next di- amictite unit (Fig. 5). A huge ignimbrite sheet un- derlies two diamictite units (diamictite units 5 and 6) which are separated by a very thin lava flow (0.1-1 m thick). The lower bed (unit 5) was probably formed by localized mass flow processes. It rests on a thin sco- riaceous lava-top which has been broken up in places and incorporated within the diamictite unit. The scori- aceous top of the lava is filled with fine laminated silt and clay, and the base of the diamictite is almost clast supported. It becomes more matrix rich towards the top but still includes boulders up to 3 m in diameter. Its matrix contains a considerable amount of glass and angular rock fragments similar to the stratigraphically JÖKULL, No. 40, 1990 13

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