Abstract
Mountain seasonal snow cover is undergoing major changes due to global climate change. Assessments of future snow cover usually rely on physical based models, and often include post-processed meteorology. Alternatively, here we propose a direct statistical adjustment of snow cover fraction from regional climate models by using long-term remote sensing observations. We compared different bias correction routines (delta change, quantile mapping, and quantile delta mapping) and explore a downscaling based on historical observations for the Greater Alpine Region in Europe. All bias correction methods adjust for systematic biases, for example due to topographic smoothing, and reduce model spread in future projections. Averaged over the study region and whole year, snow cover fraction decreases from 12.5 % in 2000–2020 to 10.4 (8.9, 11.5; model spread) % in 2071–2100 under RCP2.6, and 6.4 (4.1, 7.8) % under RCP8.5. In addition, changes strongly depended on season and altitude. The comparison of the statistical downscaling to a high-resolution physical based model yields similar results for the altitude range covered by the climate models, but different altitudinal gradients of change above and below. We found trend-preserving bias correction methods (delta change, quantile delta mapping) more plausible for snow cover fraction than quantile mapping. Downscaling showed potential but requires further research. Since climate model and remote sensing observations are available globally, the proposed methods are potentially widely applicable, but are limited to snow cover fraction only.
Highlights
Mountain regions store large amounts of precipitation in form of snow and ice, which provide essential water supply for 25 downstream regions, affecting an estimated quarter of humanity (Immerzeel et al, 2020)
3.1 Bias correction of snow cover fraction We compared four different bias correction methods, which are routinely applied for temperature and precipitation series, in their applicability for bias correcting snow cover fraction: delta change (DC), quantile mapping (QM, Gudmundsson et al, 170 2012), quantile delta mapping (QDM, Cannon et al, 2015), and multivariate QDM (Cannon, 2018)
Applying DC, QM and QDM bias correction to past regional climate models (RCMs) output enforced it to match the distribution of observed snow cover fraction (SNC) and 275 reduced the model spread for the future (Fig. 3)
Summary
Mountain regions store large amounts of precipitation in form of snow and ice, which provide essential water supply for 25 downstream regions, affecting an estimated quarter of humanity (Immerzeel et al, 2020). Global warming resulted in significant changes of the cryosphere with melting glaciers and shifts in the timing and abundance of snow (Huss et al, 2017), which already affected the hydrological cycle (Morán-Tejeda et al, 2014) and will continue to do so in the future (Hanzer et al, 2018). These changes imply consequences in water supplies for domestic use, hydropower, and agriculture.
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