Abstract
Abstract. Daily measurements of snow depth and snowfall can vary strongly over short distances. However, it is not clear if there is a seasonal dependence in these variations and how they impact common snow climate indicators based on mean values, as well as estimated return levels of extreme events based on maximum values. To analyse the impacts of local-scale variations we compiled a unique set of parallel snow measurements from the Swiss Alps consisting of 30 station pairs with up to 77 years of parallel data. Station pairs are usually located in the same villages (or within 3 km horizontal and 150 m vertical distances). Investigated snow climate indicators include average snow depth, maximum snow depth, sum of new snow, days with snow on the ground, days with snowfall, and snow onset and disappearance dates, which are calculated for various seasons (December to February (DJF), November to April (NDJFMA), and March to April (MA)). We computed relative and absolute error metrics for all these indicators at each station pair to demonstrate the potential variability. We found the largest relative inter-pair differences for all indicators in spring (MA) and the smallest in DJF. Furthermore, there is hardly any difference between DJF and NDJFMA, which show median variations of less than 5 % for all indicators. Local-scale variability ranges between less than 24 % (DJF) and less than 43 % (MA) for all indicators and 75 % of all station pairs. The highest percentage (90 %) of station pairs with variability of less than 15 % is observed for days with snow on the ground. The lowest percentage (30 %) of station pairs with variability of less than 15 % is observed for average snow depth. Median differences of snow disappearance dates are rather small (3 d) and similar to the ones found for snow onset dates (2 d). An analysis of potential sunshine duration could not explain the higher variabilities in spring. To analyse the impact of local-scale variations on the estimation of extreme events, 50-year return levels were quantified for maximum snow depth and maximum 3 d new snow sum, which are often used for avalanche prevention measures. The found return levels are within each other's 95 % confidence intervals for all (but three) station pairs, revealing no striking differences. The findings serve as an important basis for our understanding of variabilities of commonly used snow indicators and extremal indices. Knowledge about such variabilities in combination with break-detection methods is the groundwork in view of any homogenization efforts regarding snow time series.
Highlights
Snow, in all its forms, is of great social and environmental importance
The variability of the measured snow quantities on the 1 km scale may be smaller than the variability on the 10 m scale. This bias introduced by sometimes-not-ideal measuring locations that may be season dependent as we hypothesize that the wind impact is mostly relevant during the accumulation season and the solar impact during the ablation season
To be able to compare and quantify the differences of the various snow climate indicators, we use relative percentage differences (RPDs), calculated according to Eq (1) for each indicator (i) and station pair (X–Y ), with the number of years denoted by n and k indicating the actual year
Summary
In all its forms, is of great social and environmental importance. Implications can be found in many fields as diverse as ecology, climatology, hydrology, tourism, and natural hazards. Manual measurement locations sometimes do not fulfil these basic requirements for many reasons, such as the availability of suitable terrain and observers or easy access to the site Due to this fact, the variability of the measured snow quantities on the 1 km scale (i.e. next to an open field) may be smaller than the variability on the 10 m scale (e.g. south or north of a house). The variability of the measured snow quantities on the 1 km scale (i.e. next to an open field) may be smaller than the variability on the 10 m scale (e.g. south or north of a house) In theory, this bias introduced by sometimes-not-ideal measuring locations that may be season dependent as we hypothesize that the wind impact is mostly relevant during the accumulation season (availability of loose snow) and the solar impact during the ablation season (more available melt energy). This information is invaluable in view of homogenization efforts of snow data series
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