Glacier changes in the marginal zone of Sólheimajökull (e.g. Dunai, 2010). The sampled surfaces appeared fresh and unweathered, and we corrected for slope and topographic shielding (Dunai, 2010). The sam- ples were dated using the cosmogenic 36Cl nuclide. Samples were processed at the PRIME Lab at Purdue University, Indiana, USA. For calculation of the ex- posure age, geochemistry and specific gravity of the sample must be known. The samples were analyzed by Activation Laboratories (ACTLABS), Canada, by a combination of lithium metaborate/tetraborate fu- sion inductively coupled plasma mass spectrometry (ICPMS) for major elements and by traditional solu- tion ICPMS for trace element analysis using a Perkin Elmer Sciex ELAN 6000 ICPMS. Cl concentrations were determined by instrumental neutron activation analysis (INAA) and B was analyzed by prompt gamma neutron activation analysis (PGNAA). Spe- cific gravity was determined on drilled cores from the samples by ACTLABS. Ages were calculated using the PRIME Lab calculator which computes surface exposure ages according to Phillips et al. (2001). RESULTS Geomorphology of the Sólheimajökull forefield The glacier forefield is dominated by numerous end-moraine and lateral-moraine ridges dissected by glaciofluvial erosion (Figures 3–4). The moraine ridges are generally best preserved east of the river Jökulsá á Sólheimasandi. The proximal 2 km of the glacier forefield are formed by glacier advances dur- ing the LIA and later. The end-moraine ridges in this part of the forefield are 1–2 m high, 5–10 m wide, and can be traced as up to 400 m long ridge segments. River-cut sections show that the ridges consist mainly of diamict. The ridges display moderately developed saw-tooth pattern that mirror splaying crevasses and small sub-lobes of the palaeo-ice margins (Figures 4 and 5B). Minor ponds or peat bogs occur immedi- ately proximal to many end-moraine ridges, resem- bling small-scale hill-hole pairs. The most prominent end-moraine ridges represent the major LIA glacier advances (Krüger et al., 2010). A distinct end-moraine ridge marks the outermost position of the advance that culminated in 1995. This ridge is sharp-crested, 2–3 m high and 5 m wide. The ridge is cut by fluvial erosion into small segments of up to 100 m in length. It consists of diamict with several large boulders deposited on the ridge. The aerial photographs from 1996 document the age of this ridge, and show that it was initially more contin- uous. Proximal to the end moraine from 1995, small moraine ridges occur. They are well-defined, up to 0.4 m high and 0.5–1 m wide, and occur in segments up to 200 m in length. Field observations in the forefield since 2004 confirm that the ridges are annual moraines forming at the peak of each winter advance by the end of the accumulation season (Figures 4 and 5C). Their preservation potential is low due to fluvial ero- sion, heavy rain, snowmelt, and tourist traffic. The most prominent landforms in the Sólheima- jökull forefield are the lateral moraines to the south- east of the glacier (Figures 4 and 5A). They constitute distinct ridges, up to 5 m high, 15–20 m wide, and up to 1300 m long. The lateral moraines are com- posed of diamict and numerous boulders are scattered on their surface. The central part of the most distal lat- eral moraine is located at 380 m a.s.l., approximately 150 m above the current (2010) lateral glacier margin. Similar lateral moraines occur above the valley side further south (Figure 4). One distinct lateral moraine was identified above the western valley side. Between the end-moraine ridges in the central forefield, the landscape is characterized by ground moraine. Small drumlins or drumlinoids up to 35 m in length and with a c. 2 m relief occur between the ridges (Figure 4 and 5B). It is likely that these small drumlins represent overridden, streamlined remnants of end moraines. A section in one drumlin proximal to the 1995 end moraine reveals a core of extremely firm basal till (Schomacker et al., 2010). Up to 50 m long flutes are present in the recently deglaciated ter- rain proximal to the 1995 end moraine. Similar to the annual moraines, they have a very low preservation potential and rapidly weather away. In the ice-marginal area, where the glacier is cur- rently retreating into a depression, large outwash fans and an esker are underlain by dead-ice (Figure 4 and 5F). The esker is still emerging from the glacier, re- vealing a sinuous 7–10 m high ridge of coarse gravel JÖKULL No. 62, 2012 115

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