In this study, the snow conditions of South-Central Slovakia (Inner Western Carpathians; temperate zone) were analyzed to assess the suitability for ski slope operations without snow production under 1000 m a.s.l. For the study site of the Košútka Ski Centre, meteorological conditions for snowmaking, snowpack characteristics, and snow water equivalent (SWE) compared with seasonal precipitation were identified. To identify the months suitable for snowmaking, the number of potential snowmaking days (PSD) and the required number of snowmaking days (RNSD) were calculated for six winter seasons from 2010-2011 to 2015-2016. The results showed that the conditions of natural snow cover were not appropriate for ski slope operation because of a low natural snow depth. For the Košútka Ski Centre, it was concluded that the essential base layer snowmaking for ski slope operation is possible only for a few days in the winter season because of the increasing mean value of the mean average daily temperature and the consequently higher occurrence of liquid precipitation in the winter season. Essential high snow production results in the heterogeneous distribution of snow on the ski slope, and in high snow depth, density, and SWE of the ski slope snowpack, and in prolonged melting.
Presented paper deals with the quantification of greenhouse gas emissions from forest fires. The investigation was based on the inventory methodology of the Intergovernmental Panel on Climate Change from the year 2006. We describe the proposal of our methodology for estimating the required biomass for modelling (using the available literature as well as Sibyla growth simulator), and subsequently we describe the modelling process with fuel models (using FCCS model) as well as the resulting greenhouse gas emissions (using FARSITE and CONSUME model) for the selected site called Krompľa -Tri Kopce in the Slovak Paradise National Park in the cadastral area of Hrabušice, in which fire destroyed an area of 80 ha in the year 2000. From the forest typology point of view, following groups of forest types are dominant at the site: Fagetum dealpinum (Limestone beech forests); Fageto-Abietum (Neutrophilous beech forests), Pinetum dealpinum (Carpathian relict calcicolous Scots pine forests), Fagetum typicum (Limestone beech forests), Fageto-Aceretum (Mixed ravine and slope forests). The results indicate that the conceptions differ in the quantification of biomass available for burning, which was underestimated in the case of TIER 1 conception in comparison to TIER 2 and TIER 3, and also in the quantification of emissions. The emissions produced during the flameless burning phase were underestimated, while the CO2 emissions were slightly overestimated when comparing TIER 2 and TIER 3 approaches. The final assessment of the whole process points out at the problematic issues in the calculations of GHG emissions.
Mikloš M., Vyskot I., Šatala T., Korísteková K., Jančo M., Škvarenina J.: Effect of forest ecosystems on the snow water equivalent in relation to aspect and elevation in the Hučava river watershed, Poľana Biosphere Reserve (Slovakia). Ekológia (Bratislava), Vol. 36, No. 3, p. 268-280, 2017.The aim of this work was to assess how forest ecosystems dominated by Norway spruce (Picea abies (L.) or European beech (Fagus sylvatica L.) affect snow water equivalent (SWE) in relation to aspect and elevation. The research plots were established in a small headwater watershed of the Hučava flow belonging to the Poľana Biosphere Reserve (Central Europe, Inner Western Carpathians). The SWE values in this watershed (approximately 580-1270 m a.s.l.) were monitored during the three winter seasons starting from 2012−2013 to 2014−2015. The results revealed high variability in SWE and in snow cover duration between the studied seasons. The spatial variability was significantly affected by the forest ecosystem, aspect and elevation. The seasonal mean SWE value was lower by about 50−60% in the spruce forests and by about 21−30% in the beech forests compared to the open areas (100%). Over the whole seasons, the whole watershed mean SWE value on the slopes with the northern aspect was mostly higher compared to the slopes with the southern aspect. The effect of aspect was significant mainly in the open areas and in the forests dominated by European beech during the ablation periods of every season. In the case of the sufficient snow cover, the mean SWE value always increased with elevation. The elevation gradient of SWE was steepest at the open areas of the watershed in the peaks of the winter seasons. The threeseason mean value of SWE elevation gradient (per 100 m) at the time of snow accumulation peak was equal to 16 mm in the spruce forests, 20 mm in the beech forests and 26 mm in the open areas. The research revealed that SWE is significantly affected by the forest ecosystem whilst its effect is dependent on the occurrence of dominant deciduous or coniferous tree species. However, the effect of forests is closely related to topographic characteristics (aspect and elevation) of a locality.
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