Jökull


Jökull - 01.01.2012, Page 182

Jökull - 01.01.2012, Page 182
Í. Ö. Benediktsson (2008) identified a positive relationship between the size of the end moraine and the magnitude of defor- mation. Section 3 exposes the largest parts of the 1890 end moraine and shows by far most strain whereas section 1 occurs in a low ridge and reveals the least strain. These two can therefore be regarded as end members in a structural continuum of the 1890 end moraine. Sections 0 and 2 connect the two end mem- bers with intermediate strains and deformation styles that to some extent resemble those observed in sec- tions 1 and 3. As concluded by Benediktsson et al. (2008), high porewater pressure, generated by the loading of the ice and drainage retardation due to low permeabil- ity of the overall fine-grained sediments, decreased the shear strength and led to the original failure of the submarginal sediment and the formation of the marginal sedimentary wedge. The actual end-moraine ridge formed at the last day of the 1890 surge when the glacier became coupled to the bed and ploughed into the reverse slope of the marginal sediment wedge. The coupling was most likely caused by a drop in submarginal porewater pressure associated with pore- water blow-out in front of the ice, and took place a few metres to a few tens of metres upglacier from the terminal position of the surge, as carefully esti- mated from the horizontal shortening within the dif- ferent sections. New analysis of the structural ele- ments within the end-moraine ridge shows that the structural evolution of the moraine ridge was more complex than previously described by Benediktsson et al. (2008). It is proposed that the moraine ridge de- veloped through polyphase deformation in the sense that the phases of deformation are different (duc- tile, brittle) and temporally separated; ductile defor- mation dominated and occurred during high porewa- ter pressures and preceded brittle deformation, which was induced when porewater pressures decreased (cf. Phillips et al., 2011; Ferguson et al., 2011). The for- mation of the moraine ridge is considered to have started with a small-scale folding and subsequent thrusting of strata which later formed the central part of the moraine ridge (Figure 8A). Subsequently, open anticline-syncline pairs formed an upper unit of lower strain as overlying strata were pushed and sheared over the central part. This interpretation is based on asymmetric box folds and sheath folds just below the anticline-syncline pair in section 1 and normal faults below the anticline in section 2. Simultaneously, the central part of the moraine deformed further, possibly obliterating some of the original deformation struc- tures and resulting in tectonic foliation and homog- enization (Figure 8B). As the ice continued to push and porewater pressures remained high, the amplitude of the original anticlines and synclines increased and they started to overturn. Thrusting occurred in the distal and proximal extremities of the moraine ridge, possibly because of a local and temporary drop in porewater pressure, as suggested by sections 1 and 2a (Figure 8C). Further pressure caused the central anti- cline to refold to form polyclinal overturned folds and the original synclines became deeper and narrower. New folds developed and overturned in the proximal part accompanied by thrusting. Upglacier verging an- ticlines began to develop in the distal extremity of the ridge due to an obstruction in front of the ridge, most likely a patch of permafrost, which generated a counter stress towards the advancing ice (Benedikts- son et al., 2008, 2010; Thomas and Chiverell, 2011; Figure 8D). At the very end of the surge, the system locked up as porewater pressure dropped and effec- tive stress increased following porewater blow-out in front of the moraine ridge. This stiffened the entire wedge sequence and induced brittle deformation as seen from faults overprinting folds in sections 2 and 3, in particular (Figure 8E). The ductile and brittle structures in the sections suggest deformation during high and low porewa- ter pressure, respectively. Ductile deformation domi- nated the construction of the moraine ridge, indicat- ing that porewater pressure in the submarginal and proglacial sediments was generally high. However, faults and shears that formed during the earlier stages of the moraine formation (e.g. section 1 and 2) sug- gest that porewater pressure fell slightly and tempo- rary and locally locked the system to induce brittle deformation until porewater pressure rose again and ductile deformation continued. The greatest drop in porewater pressure occurred at the very end of the surge following a serious porewater blow out in front 180 JÖKULL No. 62, 2012
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