Remote sensing of snow patches on Tröllaskagi Peninsula, N-Iceland be ≥0.11 (Paul et al., 2016). For Landsat-5/-7 and -8 the blue band (Band 1 and 2 respectively) must be ≥0.15–0.2 (usually 0.16) and the SWIR 1 band ≤0.2. The blue bands and NIR (Band 5 for Landsat- 5/-7 and Band 6 for Landsat-8) distinguishes snow from clouds. The threshold values indicate spectral reflectance (Dozier, 1989; Paul et al., 2016). PSPs believed to be induced by avalanches were identified and excluded using a digital elevation model (DEM is50v, 2009), provided by LMI. For avalanches, the slope angle is one of the most im- portant parameters and it is well-known that most avalanches are released from slopes between 30◦ and 50◦ (e.g. Bühler et al., 2013; Schweizer et al., 2003; McClung and Schaerer, 2006). These angles might be slightly different depending on snow and weather con- ditions and therefore we considered slopes between 25◦ and 55◦ as potential avalanche areas. Besides slope angle, slope curvature also had to be considered for identification of avalanche channels. We classi- fied slope curvature in convex and concave areas and excluded convex shaped areas from the classification: i) Plan concave areas: plan curvature < -0.2, ii) plan convex areas: plan curvature > 0.2 and iii) flat areas: -0.2 < plan curvature < 0.2. The resolution of the DEM was 25 m which is suitable for detecting most avalanche channels, except very small ones (Mag- gioni and Gruber, 2003). Furthermore, the perime- ter of the channels was determined and areas with a small perimeter (smaller than 500 m) were excluded, because they represent very small channels that are most likely not avalanche channels. Glaciers were identified based on the Randolph Glacier Inventory 6.0 (RGI) and, where needed, man- ually corrected, because the debris covered part was not always identified correctly. Glacier areas were ex- cluded from further analyses. To investigate if snow patches occur in the same areas over a longer time period, snow patches from different years were in- tersected. The snow patches were grouped into five time periods: (i) including Landsat-5 images from the 80’s and 90’s, (ii) including Landsat-7 images from around the turn of the millennium, (iii) includ- ing Landsat-8 and Sentinel-2 images from 2013 until 2016, (iv) including all available years until 2016 and (v) including all available years until 2017. Unfortu- nately, in May 2003 one of the sensors of Landsat- 7 broke, therefore subsequent images were not suit- able for this study (Allen et al., 2010), and subse- quently we missed a period of 11 years (2003–2013). Further, the classified PSPs were compared with or- thophotos, aerial images and field photos for valida- tion purposes. In a final stage the likelihood of oc- currence of seasonal overlapping snow patches was determined. The PSP distribution of each year was intersected and where snow patches occur more often the probability that permafrost occurs in this area is higher. In the field, we have analysed and photographed the snow patches. We measured the thickness of the snow pack and of the underlying ice layer and checked for the occurrence of ice in the soil surrounding the snow patch. RESULTS In the following section results of the PSP classifica- tion and the comparison with aerial images, orthopho- tos and field work photos are presented. Further re- sults are in appendix A. Perennial Snow Patch Classification In the Brimnesdalur valley, only a few snow patches were identified during 1986–2017 period (Figure 2 and Table 3). The snow patches in Brimnesdalur were about twice as large from 1999 until 2002 (Figure 2b) and 2013 until 2016 (Figure 2c), compared to the other periods. Between 2016 (Figure 2d) and 2017 (Figure 2e) the snow fields in Brimnesdalur decreased in extent by 0.0918 km2 or 25%, suggesting intensive ablation during the summer/autumn 2017. A similar temporal pattern is observed for Kerling in the same periods (Figure 3), where the PSP maximum snow ex- tent occurs between1999 and 2002 (Figure 3b) and from 2013 until 2015, but is strongly reduced in 2016 and 2017 (Figure 3d, 3e). In Almenningar snow patches do not intersect be- tween any of the investigated periods, but snow occurs in some years. In both Almenningar and Úlfsdalir the largest snow-covered area is determined between 1986 and 1990 but is almost as large in the period JÖKULL No. 69, 2019 109

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