Glacier changes in the marginal zone of Sólheimajökull (Figures 3-4). This places the margin c. 4 km fur- ther south than today. According to Dugmore (1989), some of the lateral moraines overlie soils formed 3.1– 1.7 kyr BP but are overlain by soils of ages up to 1.2 kyr BP. Firmly established tephrochronology by Dug- more et al. (2000) indicate that the lateral moraines were deposited 1.4–1.3 kyr BP. Maizels (1991) de- scribes a fan of jökulhlaup sediments (Húsa Fan) with an apex suggesting that meltwater drained through Ystagil and the neighbouring canyon to the east, Hóls- árgil, at the time of deposition, which is consistent with an extended glacier. 14C datings of wood in the fan indicate that it is younger than 2060 yr BP. The di- rect dating of the lateral moraines with CED therefore suggests ages that are 500–600 years older than the tephrochronologically established ages (Dugmore et al., 2000). The ’outlier’, SOL-02, however, suggests an age 200 years younger than the previously estab- lished ages. This highlights the challenging large un- certainties associated with such young samples (Ta- ble 4). Sample SOL-01 of striated basalt from the top of Jökulhaus indicates that this bedrock knob was deglaciated 1.7 kyr BP. Because this predates the LIA, it is suggested that the very top of Jökulhaus was not ice-covered during the LIA, unless subglacial erosion was too little to zero the ’cosmogenic clock’ in the rock. The two 14C datings from section 2 indicate de- position of organic material in AD 1512–1539 (Ta- ble 3). This is in the early LIA, and section 2 sug- gests that Sólheimajökull advanced after that time, de- positing the end moraine ridge. According to Thor- arinsson (1943), the LIA advances of Sólheimajök- ull culminated in AD 1705, 1794 and 1820. Dug- more (1989) concluded that the end moraine ridges and other glacial landforms in the outermost part of the valley originate from advances in the 10th century AD. This implies that the upper tills (units 9-11) of section 1 are most likely from the 10th century AD and, hence, the sediments below are older than that. The time series of DEMs (Figures 9–11) display a spatial view of the glacier snout changes 1960–2010 and are important supplements to the ice marginal measurements (Figure 2). Future work on the DEM time series from Sólheimajökull should focus on com- pletely covering the entire glacier surface in order to be able to produce more spatially complete change maps and derive the total volume change and geodetic mass balance. Similar maps have successfully quanti- fied the thickness of surged glacier margins of Vatna- jökull (Magnússon et al., 2005) and long-term spa- tial changes of glaciers (Barrand et al., 2010; Mo- tyka et al., 2010). Recently, Aðalgeirsdóttir et al. (2011) pointed out the value of time-series of DEMs to force and constrain models of glacier mass balance and ice flow. Thus, good data covering the 20th cen- tury glacier history are important prerequisites to sim- ulate future glacier response to climate in the 21st century. As more high-resolution and high-accuracy DEMs become available, changes in glacier forefields (erosion/deposition) can also be identified and quanti- fied on difference DEMs (e.g. Schomacker and Kjær, 2007; Schomacker, 2008). CONCLUSIONS The forefield of the Sólheimajökull outlet glacier was shaped by glacier oscillations during the late Holocene. The most prominent landforms are numer- ous series of end moraines, some of which have a saw- tooth pattern. Southeast of the present glacier, very distinct lat- eral moraines are present. They are up to 1300 m long and document a much larger extent of Sólheimajökull than presently. Cosmogenic exposure datings suggest that the lateral moraines formed c. 1.9 kyr BP which is 500–600 years older than previously documented by tephrochronology. Hence, where accurate tephrochronological dating is available, it becomes obvious that cosmogenic dating is not comparable in either precision or accuracy. However, in many set- tings cosmogenic exposure dating is the only option, and the method has a good potential although the ac- curacy should not be expected to be as high as with tephrochronology, particularly not for young samples. 14C datings of organic material document that the LIA advances took place after AD 1539. The Little Ice Age advances were much more restricted than the advance delimited by the prominent lateral moraines. JÖKULL No. 62, 2012 127

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