Details

Autor(en) / Beteiligte

• Vetter, Tobias
• Reinhardt, Julia
• Flörke, Martina
• van Griensven, Ann
• Hattermann, Fred
• Huang, Shaochun
• Koch, Hagen
• Pechlivanidis, Ilias G.
• Plötner, Stefan
• Seidou, Ousmane
• Su, Buda
• Vervoort, R. Willem
• Krysanova, Valentina

Titel

Evaluation of sources of uncertainty in projected hydrological changes under climate change in 12 large-scale river basins

Ist Teil von

• Climatic change, 2017-04, Vol.141 (3), p.419-433

Ort / Verlag

Dordrecht: Springer Netherlands

Erscheinungsjahr

2017

Link zum Volltext

Quelle

SpringerLink (Online service)

Beschreibungen/Notizen

• This paper aims to evaluate sources of uncertainty in projected hydrological changes under climate change in twelve large-scale river basins worldwide, considering the mean flow and the two runoff quantiles Q 10 (high flow), and Q 90 (low flow). First, changes in annual low flow, annual high flow and mean annual runoff were evaluated using simulation results from a multi-hydrological-model (nine hydrological models, HMs) and a multi-scenario approach (four Representative Concentration Pathways, RCPs, five CMIP5 General Circulation Models, GCMs). Then, three major sources of uncertainty (from GCMs, RCPs and HMs) were analyzed using the ANOVA method, which allows for decomposing variances and indicating the main sources of uncertainty along the GCM-RCP-HM model chain. Robust changes in at least one runoff quantile or the mean flow, meaning a high or moderate agreement of GCMs and HMs, were found for five river basins: the Lena, Tagus, Rhine, Ganges, and Mackenzie. The analysis of uncertainties showed that in general the largest share of uncertainty is related to GCMs, followed by RCPs, and the smallest to HMs. The hydrological models are the lowest contributors of uncertainty for Q 10 and mean flow, but their share is more significant for Q 90 .