Tussetschläger et al. neath and around several PSPs was observed in the Kerling, Búrfellsdalur and Sakka areas, but not stud- ied in detail; therefore it is difficult to reach conclu- sions regarding an accurate distribution of permafrost around those snow patches. However, the occurrence of at least sporadic permafrost in Brimnesdalur, Búr- fellsdalur and Kerling is considered very likely, due to the high occurrence of PSPs, observed frozen ground proximal to the PSPs and their very high likelihood of occurrence. Damm and Langer (2006) point out, if the distribution probability of PSPs is low, espe- cially in lower elevations, then external influences have to be considered (depressions, avalanche chan- nels, windward–lee site situations etc.). Results from Etzelmüller et al. (2007) and Farbrot et al. (2007b) and Lilleøren et al. (2013) suggest that permafrost is widespread at sites where the MAAT is below -2 to -3◦C which is at elevations above 800–900 m a.s.l. in the Tröllaskagi peninsula. Recent slope movements in Tröllaskagi also confirm scattered permafrost at around 800 m a.s.l. (Sæmundsson, 2018; Morino et al., 2019). Figure 8 shows PSPs plotted on the MAAT from 1961 to 1990 (Icelandic Met. Office), many PSPs occur on elevations where discontinuous per- mafrost is most likely present. The widespread snow patch distribution above 800 m a.s.l. in the Brimnesdalur, Kerling and Búrfells- dalur areas is considered to be related with at least sporadic permafrost. In the lower Almenningar and Úlfsdalir areas only few snow patches occur for long periods with lower distributions, but many are below the MAAT -3◦C isotherm. In the Sakka region at 600– 700 m a.s.l. the snow patches only occur with lower distributions and therefore, occurrence of permafrost is not likely. However, at higher elevations some snow patches have a higher likelihood to occur and per- mafrost is more likely. Based on the results of our study, we believe that PSPs with a high likelihood of occurrence, which oc- cur over long time periods and are widespread, are good indicators for local permafrost distributions, es- pecially used in combination with MAAT. Avalanche channels should be ignored, because PSPs in those channels do not represent the lower boundary of per- mafrost in the research area. CONCLUSIONS Optical satellite images, especially Landsat-5/-7/-8 and Sentinel-2, have a great potential in mapping PSPs due to an increased temporal resolution and spa- tial resolution. This study presents a PSP detection methodology, based on optical satellite images and a digital elevation model, which is used to identify the distribution and evolution of PSPs in six study areas on the Tröllaskagi peninsula. The algorithm calcu- lates the NDSI to derive a binary snow classification excluding avalanche channels derived from a DEM. An intercomparison with independent data shows that snow is classified with confidence. Different periods of PSP coverage are evaluated to show the evolution of the snow patch distribution over a longer time pe- riod. Due to frequent heavy cloud cover, six study areas were selected to increase the number of suitable satellite images. Still, in some cases the quality of the images is not satisfying, due to cloud cover or ac- quisition timing. Several datasets, i.e. aerial images, orthophotos and field work photos, are used to evalu- ate the quality of the classification method. The inter- comparison is complicated by the fact that data is only available for some years and when available, often not acquired on the same day or even month. Snow cover extent varies between the areas and time periods due to different local characteristics, e.g. elevation, aspect or topography (e.g. plateau/open slopes vs. valley). The greatest extent of the snow patches occurs during periods of high winter precip- itation, while minimum extent occurs during periods of low winter precipitation and relatively high sum- mer temperature. In Brimnesdalur not only the largest snow patches are detected but also the highest prob- abilities of the snow patches occurring are identified. However, the distribution pattern of mapped PSPs in all study areas is similar in each time period. Conclu- sively, the PSPs in each area and each time period are often in potential permafrost areas (elevations above 800 m a.s.l.) and therefore, we suggest that PSPs can be used as a local permafrost indicator, if the snow patches reappear in multiple years (more than 2 years) and not only a single snow patch is located in the area of interest but several. 118 JÖKULL No. 69, 2019

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