Intercomparison of different uncertainty sources in hydrological climate change projections for an alpine catchment (upper Clutha River, New Zealand)
As climate change is projected to alter both temperature and precipitation, snow-controlled mid-latitude catchments are expected to experience substantial shifts in their seasonal regime, which will have direct implications for water management. In order to provide authoritative projections of clima...
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Veröffentlicht in: | Hydrology and earth system sciences 2018-06, Vol.22 (6), p.3125-3142 |
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Zusammenfassung: | As climate change is projected to alter both temperature and precipitation,
snow-controlled mid-latitude catchments are expected to experience
substantial shifts in their seasonal regime, which will have direct
implications for water management. In order to provide authoritative
projections of climate change impacts, the uncertainty inherent to all
components of the modelling chain needs to be accounted for. This study
assesses the uncertainty in potential impacts of climate change on the
hydro-climate of a headwater sub-catchment of New Zealand's largest catchment
(the Clutha River) using a fully distributed hydrological model (WaSiM) and
unique ensemble encompassing different uncertainty sources: general
circulation model (GCM), emission scenario, bias correction and snow model.
The inclusion of snow models is particularly important, given that (1) they
are a rarely considered aspect of uncertainty in hydrological modelling
studies, and (2) snow has a considerable influence on seasonal patterns of
river flow in alpine catchments such as the Clutha. Projected changes in
river flow for the 2050s and 2090s encompass substantial increases in
streamflow from May to October, and a decline between December and March. The
dominant drivers are changes in the seasonal distribution of precipitation
(for the 2090s +29 to +84 % in winter) and substantial decreases in
the seasonal snow storage due to temperature increase. A quantitative
comparison of uncertainty identified GCM structure as the dominant
contributor in the seasonal streamflow signal (44–57 %) followed by
emission scenario (16–49 %), bias correction (4–22 %) and snow
model (3–10 %). While these findings suggest that the role of the snow
model is comparatively small, its contribution to the overall uncertainty was
still found to be noticeable for winter and summer. |
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ISSN: | 1607-7938 1027-5606 1607-7938 |
DOI: | 10.5194/hess-22-3125-2018 |