After completion of the course, the student should be able to
classify and understand different types of models in hydrology
use hydrological models for flood forecasting, water resources assessment, impact assessment of climate change and land-used change
evaluate hydrological models with respect to their applications on gauged and ungauged basins and on stationary/non-stationary climatic conditions
apply commonly occurring parts/equations of which a groundwater or runoff model is constructed and thus understand how the model can and cannot be used
evaluate groundwater resources using pumping data.
estimate non-reactive and reactive contaminant spreading in groundwater
apply models to geologically heterogeneous systems by means of geostatistical approaches and the estimation of uncertainties
Mathematical description of basic processes: precipitation, evaporation, snow-melt, runoff, soil-water dynamics and groundwater recharge. Calibration, parameter optimisation, validation of run-off and groundwater models and their inherent uncertainty. Reservoir theory. Applications of HBV and Wasmod models.
Aquifers, land subsidence and groundwater resource evaluation. Estimation of transmissivity and storativity by Theis and Jacobs methods. Contaminant (non-reactive and reactive solutes) transport in groundwater. Modelling of contaminant transport in groundwater. Parameter estimation and geostatistical/stochastic approach to groundwater modelling. Special topics in groundwater modelling. Exercise with MODFLOW and GMS packages.
Lectures, field work, computer exercises, project work.
Course assessment consists of two written exams, one for groundwater ( 7 credits) and one for runoff ( 3 credits), along with approved project work and written and oral presentation of reports (5 credits).