Abstract
Abstract. We assess the sustainability of groundwater irrigation in the Euro-Mediterranean region. After analysing the available data on groundwater irrigation, we identify areas where irrigation causes groundwater depletion. To prevent the latter, we experiment with guidelines to restrict groundwater irrigation to sustainable levels, simulating beneficial and detrimental impacts in terms of improved environmental flow conditions and crop yield losses. To carry out these analyses, we apply the integrated model of water resources, irrigation and crop production LISFLOOD-EPIC. Crop growth is simulated accounting for atmospheric conditions and abiotic stress factors, including transpiration deficit. Four irrigation methods are modelled: drip, sprinkler, and intermittent and permanent flooding. Hydrologic and agricultural modules are dynamically coupled at the daily time scale through soil moisture, plant water uptake, and irrigation water abstraction and application. Water abstractions of other sectors are simulated based on requirement data. Water may be withdrawn from groundwater, rivers, lakes and reservoirs. As groundwater is abstracted to buffer the effects of drought, we use groundwater depletion to detect unsustainable water exploitation. We characterise reported data of annual groundwater abstractions for irrigation available at country and sub-national levels. Country data are the most complete, but their spatial resolution is often coarse. While the resolution of sub-national data is finer, their coverage is heterogeneous. Simulated and reported irrigation groundwater abstractions compare well in several areas, particularly in France, while some structural discrepancies emerge: simulated values tend to be larger than those reported, especially in southern Spain; and simulated inter-annual variability is significantly smaller than reported in some areas, most remarkably in Turkey. Potential causes of these discrepancies are simplified model assumptions influencing irrigation frequency and amounts; lack of high temporal and spatial resolution data on irrigated areas, and irrigation technologies and distribution; and possible unreported abstractions in areas where groundwater irrigation is significant. We identify areas undergoing groundwater depletion from model simulations. In the southern Iberian Peninsula, Greece, Middle East and northern Africa, most simulated depletion is caused by irrigation. In other Mediterranean areas, depletion is caused by all sectors combined. From well measurements of groundwater table depth in Spain, we find statistically significant decline rates affecting large areas of the south, thus in agreement with the model, but also areas in the north-eastern and central parts where model estimates detect no depletion. The comparison of model- and well-based depletion rates is limited by spatial scale differences and groundwater model assumptions, for which we suggest potential research directions. We design rules restricting irrigation groundwater abstraction to prevent groundwater depletion and minimise severe irrigation shortages. We optimise them and simulate their effects in the southern Iberian Peninsula. Irrigation restrictions cause crop yield reductions in groundwater-dependent irrigated areas, particularly in the Algarve and Segura river basin districts. At the same time, they positively impact environmental flows. This study shows the potential of integrated agro-hydrologic modelling for detecting water resources over-exploitation and exploring trade-offs between crop production, sustainable irrigation and ecosystem support.
Highlights
Freshwater availability is put under increasing pressure by global warming, land use changes, and water abstractions (IPCC, 2019)
We present the outcomes of regulating groundwater abstraction for irrigation in the southern Iberian Peninsula (Sect. 4.3)
Basin data are reported for Water Framework Directive (WFD) river basin districts and sub-basins (RBDs) for the following countries: Austria (2010), Bulgaria (2005–2017), Croatia (2014– 2017), Czech Republic (2008, 2010–2017), France (2007– 2016), Greece (2011–2016), Hungary (2010–2015), Lithuania (2012–2017), Netherlands (2005–2012), Poland (2010– 2017), Portugal (2017), parts of Romania (2014–2015), Serbia (2012–2017), Slovakia (2005–2017), Slovenia (2010– 2017), Spain (2011–2014), Sweden (2005, 2010, 2015), Switzerland (2012), and the Brussels area in Belgium (2012– 2017)
Summary
Freshwater availability is put under increasing pressure by global warming, land use changes, and water abstractions (IPCC, 2019). Irrigation accounts for 70 % of water withdrawals and 90 % of consumptive water use globally (Shiklomanov, 2000; Molden et al, 2007; IAASTD, 2009). These figures reflect the growth of irrigated agriculture during the XX century: areas equipped for irrigation have more than quadrupled (Siebert et al, 2015), while irrigation water use has more than doubled (IPCC, 2019). In 2010, Siebert et al estimated that 43 % of global consumptive water use for irrigation was drawn from groundwater
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.