Holocene surface ruptures in the South Iceland Seismic Zone animals had perished, and holes that were useful for trash disposal. The surface in the SISZ is mainly of two different types. A good part of the zone is covered by a single lava flow, the Þjórsá lava with an estimated volume of 15 km3 (Hjartarson, 1988), that issued from the East- ern Volcanic Zone ∼8000 years ago. Other parts of the zone have basalts of the Plio-Pleistocene Hreppar for- mation as bedrock, covered by thin ground moraines left by the last glaciation. The Þjórsá lava generally preserves the fracture structures rather well and they are easily traced in spite of considerable vegetation and soil that covers parts of the lava. An open fracture tends to maintain a sinkhole in the soil cover above for a long time after its formation. Tracing fractures in the Hreppar formation and the moraine material is much more difficult. The surface erodes faster and therefore fracture manifestations tend to get erased. There is, however, no noticeable difference in the appearance of the structures if they are exposed. This was clearly demonstrated in the surface effects of the earthquakes of 2000 (Clifton and Einarsson, 2005). STRUCTURES ASSOCIATED WITH THE SURFACE FAULTS The seismogenic faults of South Iceland are clearly exposed at the surface in numerous places and can be identified by characteristic structures. The best expo- sures are in areas where the Þjórsá lava forms the sur- face bedrock layer, also where it is covered by a thin soil layer. The characteristic structures are also found in areas where the lava is lacking and glacial deposits form the surface layer but they are not as well pre- served there. En echelon fracture arrays constitute one of the most characteristic features of surface ruptures of strike-slip faults. The surface trace is marked by a deformation zone of obliquely trending fractures. Left-lateral faults are marked by right-stepping ex- tensional fractures and right-lateral faults have left- stepping fractures associated with them. In South Ice- land most of the identified fault ruptures are associ- ated with right-lateral faulting. Left-lateral faults oc- cur but almost always in a subordinate role. The en echelon structure shows up on many different length scales. The largest scale is measured in kilometers. Fault segments of one to a few km length are offset with respect to each other. This scale can be clearly seen in the faults in Figure 1. The offset between the segments is of the order of a few hundred meters to a kilometer. This offset determines the width of the fractured zone associated with the underlying fault. Each segment then displays en echelon structure. In- dividual fractures of lengths up to tens of meters are offset with respect to each other, forming en echelon fracture arrays. The pattern is sometimes repeated on a meter scale within these arrays. During the re- cent earthquakes of 2000 and 2008 this pattern was observed on a finer scale yet (Clifton and Einarsson, 2005), to centimeters and millimeters in soil surfaces (Figure 2). Push-up structures are frequently found within en-echelon fracture arrays, usually bridging the gap between the tips of adjacent extensional fractures. They have the form of small hillocks, a few tens of centimeters to a few meters in height. The horizontal dimensions and shape are quite variable. Some push- ups are almost round in shape, others are quite elon- gated. The tops of the hillocks are usually heavily fractured, sometimes to the extent of looking crushed. When fracture systems can be discerned there appear to be two separate kinds of fractures, longitudinal and transverse. The longitudinal fractures are sub-parallel to the adjacent extensional fractures and thus form a part of the en echelon pattern of the over-all frac- ture array. There may be several of these crossing the push-up (Figure 3) resembling a sliced loaf of bread, often rotated slightly with respect to the adjacent pat- tern. In a left-stepping, N-S trending array the longitu- dinal fractures would thus have slightly more easterly strike than the adjacent extensional fractures. The transverse fractures usually follow the crest of the push-up and are extensional in nature. In lava sur- faces that are not affected by other processes it can be seen how the transverse fractures occupy the crest of folded antiforms. The push-up is then seen as a minia- ture fold with axis perpendicular to the maximum hor- izontal principal stress. This structure was demon- strated well in the surface ruptures associated with the JÖKULL No. 60 121

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