Environmental Research Letters (Jan 2024)

Global hydrological models continue to overestimate river discharge

  • Stefanie Heinicke,
  • Jan Volkholz,
  • Jacob Schewe,
  • Simon N Gosling,
  • Hannes Müller Schmied,
  • Sandra Zimmermann,
  • Matthias Mengel,
  • Inga J Sauer,
  • Peter Burek,
  • Jinfeng Chang,
  • Sian Kou-Giesbrecht,
  • Manoli Grillakis,
  • Luca Guillaumot,
  • Naota Hanasaki,
  • Aristeidis Koutroulis,
  • Kedar Otta,
  • Wei Qi,
  • Yusuke Satoh,
  • Tobias Stacke,
  • Tokuta Yokohata,
  • Katja Frieler

DOI
https://doi.org/10.1088/1748-9326/ad52b0
Journal volume & issue
Vol. 19, no. 7
p. 074005

Abstract

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Global hydrological models (GHMs) are widely used to assess the impact of climate change on streamflow, floods, and hydrological droughts. For the ‘model evaluation and impact attribution’ part of the current round of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP3a), modelling teams generated historical simulations based on observed climate and direct human forcings with updated model versions. Here we provide a comprehensive evaluation of daily and maximum annual discharge based on ISIMIP3a simulations from nine GHMs by comparing the simulations to observational data from 644 river gauge stations. We also assess low flows and the effects of different river routing schemes. We find that models can reproduce variability in daily and maximum annual discharge, but tend to overestimate both quantities, as well as low flows. Models perform better at stations in wetter areas and at lower elevations. Discharge routed with the river routing model CaMa-Flood can improve the performance of some models, but for others, variability is overestimated, leading to reduced model performance. This study indicates that areas for future model development include improving the simulation of processes in arid regions and cold dynamics at high elevations. We further suggest that studies attributing observed changes in discharge to historical climate change using the current model ensemble will be most meaningful in humid areas, at low elevations, and in places with a regular seasonal discharge as these are the regions where the underlying dynamics seem to be best represented.

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