EGU2020-19277
https://doi.org/10.5194/egusphere-egu2020-19277
EGU General Assembly 2020
© Author(s) 2022. This work is distributed under
the Creative Commons Attribution 4.0 License.

Impact of improved land model depth and hydrology on climate change projections

Norman Steinert1,2, Fidel González-Rouco1,2, Stefan Hagemann3, Philipp de Vrese4, Elena García-Bustamante5, Johann Jungclaus4, Stephan Lorenz4, Camilo Melo-Aguilar1,2, and Jorge Navarro5
Norman Steinert et al.
  • 1Complutense University of Madrid, Department of Earth Sciences and Astrophysics, Madrid, Spain
  • 2Geosciences Institute, Madrid, Spain
  • 3Helmholtz-Centre Geesthacht, Geesthacht, Germany
  • 4Max Planck Institute for Meteorology, Hamburg, Germany
  • 5CIEMAT Centre for Energy, Environment and Technology, Madrid, Spain

The representation of the thermal and hydrological state in the land model component of Earth System Models is crucial to have a realistic simulation of subsurface processes and the coupling between the atmo-, lito- and biosphere. There is evidence suggesting an inaccurate simulation of subsurface thermodynamics in current-generation Earth System Models, which have Land Surface Models that are too shallow. In simulations with a bottom boundary too close to the surface, the energy propagation and spatio-temporal variability of subsurface temperatures are affected. This potentially restrains the simulation of land-air interactions and subsurface phenomena, e.g. energy/moisture balance and storage capacity, freeze/thaw cycles and permafrost evolution. We introduce modifications for a deeper soil into the JSBACH soil model component of the MPI-ESM for climate projections of the 21st century. Subsurface layers are added progressively to increase the bottom boundary depth from 10m to 1400m. This leads to near-surface cooling of the soil and encourages regional terrestrial energy uptake by one order of magnitude and more.
The depth-changes in the soil also have implications for the hydrological regime, in which the moisture between the surface and the bedrock is sensitive to variations in the thermal regime. Additionally, we compare two different global soil parameter datasets that have major implications for the vertical distribution and availability of soil moisture and its exchange with the land surface. The implementation of supercool water and water phase changes in the soil creates a coupling between the soil thermal and hydrological regimes. In both cases of bottom boundary and water depth changes, we explore the sensitivity of JSBACH from the perspective of changes in the soil thermodynamics, energy balance and storage, as well as the effect of including freezing and thawing processes and their influence on the simulation of permafrost areas in the Northern Hemisphere high latitudes. The latter is of particular interest due to their vulnerability to long-term climate change.

How to cite: Steinert, N., González-Rouco, F., Hagemann, S., de Vrese, P., García-Bustamante, E., Jungclaus, J., Lorenz, S., Melo-Aguilar, C., and Navarro, J.: Impact of improved land model depth and hydrology on climate change projections , EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-19277, https://doi.org/10.5194/egusphere-egu2020-19277, 2020.