EGU21-13070, updated on 04 Mar 2021
https://doi.org/10.5194/egusphere-egu21-13070
EGU General Assembly 2021
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

New functional topographic, lithology and climatic indices to define shallow groundwater systems in (un)gauged basins

Ardalan Tootchi1 and Ali Ameli2
Ardalan Tootchi and Ali Ameli
  • 1The University of British Columbia, Earth, Ocean and Atmospheric Sciences, Vancouver, Canada (ardalan.tootchi@gmail.com)
  • 2The University of British Columbia, Earth, Ocean and Atmospheric Sciences, Vancouver, Canada (aameli@eoas.ubc.ca)

The dynamics of the rainfall-runoff processes are complex and variable both spatially and temporally. There is a rich literature on physical representation of streamflow generation processes, such as saturation excess overland flow, often at small scales. Yet, continental-scale estimations of the streamflow generation processes in zones with shallow groundwater systems are still poor. This has led to inability of earth system models or large-scale hydrologic models to correctly simulate stream flows at (un)gauged basins with high potential for the presence of saturation excess overland flow. Zones with shallow groundwater have a direct impact on the hydrologic response of rainfall events. Depending on the subsurface storage, climate signals and topography, they can enhance the overland flow, or act as a buffer zone to flatten the flood hydrographs.
We have introduced new indices, inspired by the concept of hydrologic function, that include the interactions amongst climatic and geophysical characteristics (soil parameters, topography and lithology) to delineate zones of shallow groundwater over the United States and Canada. We have evaluated and tested the ability of these indices in locating high-resolution zones of shallow groundwater against in-situ observations of water table depth. The knowledge of the spatial pattern of shallow groundwater zones at (un)gauged basins allows an accurate inclusion of hydrologic connectivity in earth system models or large-scale hydrologic models, improving their prediction of stream peak flow. Furthermore, as a significant part of incoming precipitation is transformed to overland flow due to oversaturation, these datasets could be introduced as a useful indicator of areas with flood and erosion susceptibility.

How to cite: Tootchi, A. and Ameli, A.: New functional topographic, lithology and climatic indices to define shallow groundwater systems in (un)gauged basins, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-13070, https://doi.org/10.5194/egusphere-egu21-13070, 2021.