Department of Geoscience

Modeling Hydrological Impacts of Climate and Irrigation Changes in a Mediterranean Catchment

Catchment responses to climate and irrigation changes in a semi-arid climate

PhD Researcher: Diane von Gunten
Supervisors: Olaf Cirpka (University of Tübingen), Thomas Wöhling (TU Dresden), Claus Haslauer (University of Tübingen), David L. Rudolph (University of Waterloo)

PhD Thesis

Introduction

The ongoing climate change will have important impacts on hydrological processes, especially in semi-arid regions, where water resource is limited. The prediction of these impacts is necessary to adapt to the new conditions, but is complicated by our limited understanding of catchment sensitivity to temperature and precipitation changes. To improve this understanding, hydrological models are often used. These models are calibrated in present climate with measured data. Inputs are then modified based on various climate scenarios. Outputs of the models run in present conditions are finally compared with the outputs of the models run in future conditions.

Various hydrological models have been used for this purpose, from simple conceptual models to distributed, integrated models. However, integrated hydrological models have only rarely been used in climate-impact studies because of the long simulation time associated with this type of model [Goderniaux, 2011]. These models could however bring interesting insights into the estimation of climate change impacts, notably because of their distributed representation of water exchanges between the surface and subsurface.

Consequently, the goal of this study is to estimate and to improve the usefulness of integrated hydrological models in climate-impact studies.

Case study

Elevation of the Lerma catchement and position of the observation wells (adapted from [von Gunten, 2014])

This study is centered on one case study: The Lerma catchment, situated in north-east Spain, in the Ebro basin, about 70km west of Zaragoza. It is a relatively small catchment (about 7.3km2) used for agriculture. Its main characteristic is a rapid transition from non-irrigated to irrigated agriculture between 2006 and 2008. This transition has been well monitored by the Spanish Geological Survey [e.g., Merchan, 2013] and data on hydraulic heads, discharge, irrigation volume, and crop types are available.

The climate in the Lerma catchment is semi-arid with a mean precipitation of 400 mm/year (2004-2008) and a mean PET of 1260mm/year (id.) [Abrahao et al., 2011]. Winter (December-January) and summer (July-September) are the driest months while spring is the rainiest season. The geology of the Lerma catchement is composed of two main layers: A glacis layer on the top and a "buro" layer under it. The glacis are clastic, permeable, and unconsolidated deposits while the buro is a tertiary bedrock made of lutite and marlstones. The glacis forms an aquifer and the buro can be considered an aquitard even if its top part plays a role in the water circulation. The Lerma soils are very thin and are composed of inceptisols [Perez, 2011]. No production wells are used in this catchment for groundwater abstraction.

Efficient model calibration

Model calibration is a necessary step to apply a hydrological model to a catchment. The speed of the calibration depends on the duration of the simulation and the number of model parameters. Integrated hydrological model often have long simulation times and a large number of parameters. Hence, parameter calibration of these models is a long and tedious process in many practical cases. Consequently, model calibration is often limited to a trial-and-error process.

To accelerate model calibration, we propose a new calibration method based on a set of computational grids of increasing resolution. Model using fine grids have longer simulation time. Hence, the computational grid must be as coarse as possible but the grid must also be fine enough to represent run-off and peak-flow. However, base flow and hydraulic heads are represented acceptably in coarser grids. We propose to first calibrate the model on base flow and hydraulic heads in coarser grids and to calibrate the model on peak flow using finer grids afterwards. This method accelerates model calibration by a factor of eight in our case study.

Presentation CMWR 2014 
Grid simpli cation to accelerate calibration of integrated catchment models: Accuracy vs. effciency

Climate and irrigation changes

Base flow in present and future climate for the four regional cliamte models. Scenario 1: No irrigation, scenario 3: future irrigation

Climate change is not the only anthropogenic pressure on hydrological processes in semi-arid regions. For example, the extent of irrigated areas have increased in recent times. In the Ebro basin, this increase is planned to be about 30-50% of the actual irrigated area [Milano, 2013]. Irrigation strongly impacts the hydrology of catchment and interacts with climate change. We wanted to explore these interactions and investigate how the catchment reacts differently to climate change in irrigation conditions than in non-irrigated conditions. We use our hydrological model, which was calibrated under irrigated and non-irrigated conditions, for this research.

We find that base flow and hydraulic heads are higher in irrigated conditions, but are more sensitive to climate change in this case than in non-irrigated conditions. Peak flow are more sensitive to changes in precipitation variability in non-irrigated scenarios than in irrigated scenarios. Changes in actual evapotranspiration depend on the irrigation condition: Without irrigation, actual evapotranspiration decreases because of the decreasing summer precipitation. With irrigation, actual evapotranspiration increases because water availability and actual evapotranspiration are higher.

Poster AGU 2014 
Projected Climate Change Impacts on a Mediterranean Catchment under Different Irrigation Scenarios

Hydrological impacts of droughts

Extreme events, such as droughts, have often stronger impacts on the hydrology than average climatic changes. However, droughts can be difficult to characterize. Many droughts indices, that is, summary metrics representing the dryness level, have been developed to quantify droughts. However, because comparisons between drought indices are rare, the choice of a particular drought index can be difficult. To simply this process, we compare seven well-known drought indices to the outputs from our hydrological model in present and future conditions. We compare the correlation between modelled hydrological variables (discharge, water deficit, and hydraulic heads) and drought indices. Then, we analyze the relationships between each drougth index and the hydrological variables. Correlation coefficient are similar for all irrigation scenarios in present and future cliamtes. However, the relationships between hydrological variables and the drougth indices are sensitive to climate change.

Poster AGU 2015
Integrated Modeling of Climate Change Impacts in an Irrigated, Semi-arid Catchment (Lerma, Spain)

References

  • [Abrahao, 2011] Abrahao, R.; Causapé, J.; García-Garizábal, I. & Merchán, D. Implementing irrigation: Water balances and irrigation quality in the Lerma basin (Spain), Agricultural Water Management, 2011, 102, 97-104
  • [Goderniaux, 2011] Goderniaux, P.; Brouyère, S.; Blenkinsop, S.; Burton, A.; Fowler, H. J.; Orban, P. & Dassargues, A.Modeling climate change impacts on groundwater resources using transient stochastic climatic scenarios Water Resour. Res., AGU, 2011, 47, W12516
  • [Merchan, 2013] Merchan, D.; Causapé, J. & Abrahao, R. Impact of irrigation implementation on hydrology and water quality in a small agricultural bassin in Spain, Hydrological Sciences Journal, 2013, 58, 1400-1413
  • [Milano, 2013] Milano, M.; Ruelland, D.; Dezetter, A.; Fabre, J.; Ardoin-Bardin, S. & Servat, E. Modeling the current and future capacity of water resources to meet water demands in the Ebro basin Journal of Hydrology, 2013, 500, 114-126
  • [Pérez, 2011] Pérez, A.; Abrahão, R.; Causapé, J.; Cirpka, O. & Bürger, C. Simulating the transition of a semi-arid rainfed catchment towards irrigation agriculture Journal of hydrology, 2011, 409, 663-681

Publications

  • von Gunten, D., Wöhling, T., Haslauer, C., Merchán, D., Causapé, J., Cirpka, O.A. (2016): Using an integrated hydrological model to estimate the usefulness of meteorological drought indices in a changing climate. Hydrol. Earth Syst. Sci., doi: 10.5194/hess-20-4159-2016
  • von Gunten, D., Wöhling, T., Haslauer, C., Merchán, C., Causapé, J., Cirpka, O.A. (2015): Estimating Climate-Change Effects on a Mediterranean Catchment under Various Irrigation Conditions. J. Hydrol. Reg. Stud., 4, 550-570, doi: 10.1016/j.ejrh.2015.08.001
  • von Gunten, D., Wöhling, T., Haslauer, C., Merchán, C., Causapé, J., Cirpka, O.A. (2014): Efficient Calibration of a Distributed Pde-based Hydrological Model Using Grid Coarsening. J. Hydrol. 519, 3290-3304, doi: 10.1016/j.jhydrol.2014.10.025