Unsaturated Zone - Technical Reference
Unsaturated flow is one of the central processes in MIKE SHE and in most model applications. The unsaturated zone is usually heterogeneous and characterized by cyclic fluctuations in the soil moisture as water is replenished by rainfall and removed by evapotranspiration and recharge to the groundwater table. Unsaturated flow is primarily vertical since gravity plays the major role during infiltration. Therefore, unsaturated flow in MIKE SHE is calculated only vertically in one-dimension, which is sufficient for most applications. However, this may limit the validity of the flow description in some situations, such as on steep hill slopes with contrasting soil properties in the soil profile. MIKE SHE includes an iterative coupling procedure between the unsaturated zone and the saturated zone to compute the correct soil moisture and the water table dynamics in the lower part of the soil profile.
There are three options in MIKE SHE for calculating vertical flow in the unsaturated zone:
Richards Equation
The full Richards equation requires a tabular or functional relationship for both the moisture-retention curve and the effective conductivity.
The full Richards equation is the most computationally intensive, but also the most accurate when the unsaturated flow is dynamic.
Gravity Flow
The simplified gravity flow procedure assumes a uniform vertical gradient and ignores capillary forces.
The simplified gravity flow procedure provides a suitable solution when you are primarily interested in the time varying recharge to the groundwater table based on actual precipitation and evapotranspiration and not the dynamics in the unsaturated zone.
Two Layer Water Balance
The simple two-layer water balance method divides the unsaturated zone into two zones: the root zone and the zone between the roots and the water table.
The simple two-layer water balance method is suitable when the water table is shallow and groundwater recharge is primarily influenced by evapotranspiration in the root zone.