Sub-arctic hydrology and climate change : a case study of the Tana River Basin in Northern Fennoscandia

The most significant changes in climate, due to the well-known enhanced greenhouse effect, are generally expected to occur at northern high latitudes. Sub-arctic environments, that are dominated by the presence of a seasonal snow cover, may therefore be particularly sensitive to global warming. The...

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Bibliographic Details
Main Author: Dankers, Rutger
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: 2002
Subjects:
Aardwetenschappen
sub-arctic
climate change
hydrology
water balance
evapotranspiration
snow
remote sensing
modelling
Finland
Norway
Arctic
Barents Sea
Tana River
Climate change
Fennoscandia
Global warming
Northern Finland
Online Access:https://dspace.library.uu.nl/handle/1874/557
Description
Summary:The most significant changes in climate, due to the well-known enhanced greenhouse effect, are generally expected to occur at northern high latitudes. Sub-arctic environments, that are dominated by the presence of a seasonal snow cover, may therefore be particularly sensitive to global warming. The impact of human-induced climate changes on the hydrological system of sub-arctic environments was analysed in a series of studies, undertaken in the Tana River Basin in northernmost Finland and Norway. Central to the approach was a large-scale hydrological model of the study area, that has been coupled to a regional climate model. The hydrological model was based on a conceptual water balance model originally developed for the River Rhine. In this study, special attention was paid to the spatial distribution of snow coverage, snowmelt and evapotranspiration, in addition to river discharge. In order to be able to make proper estimates of the consequences of climate change, the empirical methods of estimating snowmelt and evapotranspiration in the water balance model were replaced by two physically-based models. In developing the hydrological model, field measurements were used that have been collected in a small catchment in Northern Finland. The model performance was evaluated by comparing the results with satellite observations of snow cover depletion in the Tana Basin, as well as observations on snow depth and river discharge. The improved, physically-based model version appeared to simulate the hydrological behaviour of the Tana Basin realistically. The impact of changes in climate was analysed by driving the hydrological model with climate change scenarios. For the Tana Basin, these scenarios imply that the mean annual temperature in the coming century may rise by more than 5 degrees Celsius, and precipitation may increase by 25 %. As a consequence, the snow-free season is extended by more than 30 days at higher elevations, to 70 days or more days close to the Barents Sea. Consequently, the amount of solar ...

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