Structural evolution of the 1890 Brúarjökull end moraine a few high-angle normal faults at 1–3 m that dip 80- 85◦ S, a high-angle backthrust at ∼7 m dipping 75◦ NE, and a number of low-angle normal faults, partic- ularly in the lower part (below 3 m) (Figure 7). The most prominent structures in the central part are large north verging, overturned polyclinal folds at 0–2 m with upglacier dipping axial planes. The white Öræfa- jökull AD 1362 tephra marker, LPT beds, and tephra layers outline the fold axis which plunges 8◦ W. The abovementioned high-angle normal faults cross-cut the folds as do thrust faults in the upper part that corre- late with the thrusts described from the section at 0–2 m (Figure 7). At ca. 1 m, the white tephra outlines an- other prominent fold but its limbs are not easily iden- tified due to intense faulting. From 4 to 6 m, there are upglacier inclined beds of LPT and tephra that are repeated upwards. These beds are thought to repre- sent multiple fold limbs while the fold hinges have ei- ther been eroded away (above) or are buried (below). In the upper part at 6–9 m, there are a number of in- clined, north-verging folds with shallow axial plunge towards west. The limbs and hinges of these folds are commonly cross-cut by high-angle normal faults and backthrusts, some of which are slightly folded and thus indicating fault formation before folding was completed. The distal slope, 9–12.7 m. The most dominant structures in this part of the section are fairly steeply inclined, south verging folds with axes plunging 4◦ towards east. This is typified, in particular, at around 12 m where black tephra and LPT beds outline the folds. The fold vergence to the south suggests an obstacle in front of the moraine that created a counter-stress from the north during the moraine-ridge formation. The deformation in section 3 probably initiated in a similar manner as in sections 0, 1, and 2, i.e. with small-scale folding of the lower strata and subsequent open folding and shearing of the upper strata across the lower part. It is suggested that sections 3 rep- resents the most developed stage in the end moraine formation with an additional phases of multiple fold- ing and faulting before the deformation ceased. The main faulting phase occurred towards the end of the moraine formation. This is evident from fre- quent cross-cutting by faults through folds. However, slightly folded fault planes indicate that faulting com- menced shortly before folding ceased. Steeply dipping normal and thrust faults are com- mon in section 3. They show little consistency in terms of orientation although the principal vector plots as dipping towards WNW. Although the orien- tation of only five fold axes could be measured di- rectly, they show remarkably strong east-west orien- tation, which corresponds to stress induced from the south or north. Thus, the fold axes seem to be a more reliable structural indicator of the direction of stress than faults (Figure 7). The general steepness of both folds and faults in the section indicates that the folds are rooted and that the glaciotectonic stress was ab- sorbed within a relatively narrow zone bounded by the glacier to the south and permafrost to the north. Due to the multiple folding and intense faulting, in particular, it is very difficult to trace marker hori- zons through the section. Therefore, it is impossible to apply line and area balancing to the entire section 3. However, and just to get a glimpse of the total hor- izontal shortening at this site, line balancing was ap- plied to the polyclinal folds at 0–2 m, through which the tephra marker horizons could be followed. This revealed a horizontal shortening of 76%, which, be- cause of the common refolding in the section, must be considered to be fairly representative for the moraine ridge at this site. POLYPHASE STRUCTURAL EVOLUTION OF THE 1980 END MORAINE Together with a marginal sediment wedge, the 1890 end moraine forms a dual, marginal end product of the 1890 surge (Benediktsson et al., 2008). Much of the deformation observed in the end-moraine ridge, par- ticularly in the proximal part, can be regarded as part of the wedge formation, and the basal décollement must therefore be common for these two ice-marginal components (Benediktsson et al., 2008). The four sections in the end moraine reveal different styles and magnitudes of deformation and by studying the mor- phology of the 1890 end moraine, Benediktsson et al. JÖKULL No. 62, 2012 179

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