H44B-08:
Event-based aquifer-to-atmosphere modeling over the European CORDEX domain

Thursday, 18 December 2014: 5:45 PM
Jessica Keune1,2, Klaus Goergen1,2, Mauro Sulis1, Prabhakar Shrestha1, Anne Springer2,3, Juergen Kusche3, Christian Ohlwein1,4 and Stefan J Kollet2,5, (1)University of Bonn, Meteorological Institute, Bonn, Germany, (2)Centre for High-Performance Scientific Computing in Terrestrial System, ABC/J Geoverbund, Jülich, Germany, (3)University of Bonn, Institute of Geodesy and Geoinformation, Bonn, Germany, (4)Hans Ertel Centre for Weather Research, Climate Monitoring Branch, Bonn, Germany, (5)Forschungszentrum Jülich, Agrosphere (IBG 3), Jülich, Germany
Abstract:
Despite the fact that recent studies focus on the impact of soil moisture on climate and especially land-energy feedbacks, groundwater dynamics are often neglected or conceptual groundwater flow models are used. In particular, in the context of climate change and the occurrence of droughts and floods, a better understanding and an improved simulation of the physical processes involving groundwater on continental scales is necessary. This requires the implementation of a physically consistent terrestrial modeling system, which explicitly incorporates groundwater dynamics and the connection with shallow soil moisture. Such a physics-based system enables simulations and monitoring of groundwater storage and enhanced representations of the terrestrial energy and hydrologic cycles over long time periods. On shorter timescales, the prediction of groundwater-related extremes, such as floods and droughts, are expected to improve, because of the improved simulation of components of the hydrological cycle.

In this study, we present a fully coupled aquifer-to-atmosphere modeling system over the European CORDEX domain. The integrated Terrestrial Systems Modeling Platform, TerrSysMP, consisting of the three-dimensional subsurface model ParFlow, the Community Land Model CLM3.5 and the numerical weather prediction model COSMO of the German Weather Service, is used. The system is set up with a spatial resolution of 0.11° (12.5km) and closes the terrestrial water and energy cycles from aquifers into the atmosphere. Here, simulations of the fully coupled system are performed over events, such as the 2013 flood in Central Europe and the 2003 European heat wave, and over extended time periods on the order of 10 years. State and flux variables of the terrestrial hydrologic and energy cycle are analyzed and compared to both in situ (e.g. stream and water level gauge networks, FLUXNET) and remotely sensed observations (e.g. GRACE, ESA ICC ECV soil moisture and SMOS). Additionally, the presented modeling system may be useful in the assessment of groundwater-related uncertainties in virtual reality and scenario simulations.

Back to: Advances in Hydrometeorological Predictions and Applications IV
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