EGU2020-5283, updated on 12 Jun 2020
https://doi.org/10.5194/egusphere-egu2020-5283
EGU General Assembly 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Modelling the water-system in the Pyrenean Aure-Louron Valley

Peng Huang1, Eric Sauquet1, Jean-Philippe Vidal1, and Natacha Dariba2
Peng Huang et al.
  • 1INRAE, UR RiverLy, 5 rue de la Doua, CS 20244, 69625 Villeurbanne Cedex, France (peng.huang@irstea.fr)
  • 2ENGIE, GEM, 34 Boulevard Simon Bolivar, 1000, Brussels, Belgium (natacha.dariba@engie.com)

The increasing demand for renewable energy renders the optimal management of the water-energy nexus highly important, and the complexity of global change compromises the sustainability of current water use. Therefore, models representing human interventions on water resource are crucial. This work takes the multipurpose reservoir system of the Aure-Louron Valley in the center of the Pyrenees as a typical study case to establish an integrated hydrological modelling framework. Hydropower and downstream consumption represent the main water uses in the study case. The work is a scientific contribution to the Interreg PIRAGUA project (https://www.opcc-ctp.org/en/piragua). Detailed work aims to develop a modelling chain that integrates a water resource model, a water demand model, and a water management model. This study focuses on the water resource model and the water demand model for energy. Water resource is characterized by the hydrological model GR6J (Riboust et al., 2019), calibrated with the SAFRAN surface reanalysis (Vidal et al., 2010) with a dedicated Pyrenean 2.5 km resolution version, and gap-filled MODIS data (Gascoin et al., 2015) for better robustness of snowpack modelling. The energy demand model is based on the air temperature of France and calendar day (Hendrickx and Sauquet, 2013). It is validated with the historical data of water used for hydropower production over the 2001-2018 period. Tools are being developped to make the models transposable to a wide range of water management contexts. The next steps of the study will focus on establishing a water demand model for downstream consumption, and a water management model. Finally, the modelling chain will be applied under various global change scenarios to assess the vulnerability of the system.

References:

Hendrickx, F. and Sauquet, E. (2013). Impact of warming climate on water management for the Ariège river basin (France). HYDROLOG. SCI. J., 58(5): 976-993.

Riboust, P., Thirel, G., Le Moine, N., and Ribstein, P. (2019). Revisiting a simple degree-day model for integrating satellite data: Implementation of SWE-SCA hystereses. J. HYDROL. HYDROMECH., 67(1): 70-81.

Vidal, J.-P., Martin, E., Franchistéguy, L., Baillon, M., and Soubeyroux, J.-M. (2010). A 50-year high-resolution atmospheric reanalysis over France with the SAFRAN system. INT. J. CLIMATOL., 30(11):1627–1644.

How to cite: Huang, P., Sauquet, E., Vidal, J.-P., and Dariba, N.: Modelling the water-system in the Pyrenean Aure-Louron Valley, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-5283, https://doi.org/10.5194/egusphere-egu2020-5283, 2020

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