Approaches and methodologies to monitor and mitigate saltwater intrusion in the Adriatic coastal plains
- 1Institute of Geosciences and Earth Resources, National Research Council, Padova, Italy
- 2Department of Civil, Environmental and Architectural Engineering (ICEA), University of Padova, Padova, Italy
- 3Faculty of Civil Engineering, Architecture and Geodesy, University of Split, Split, Croatia
- 4Department of Agronomy, Food, Natural resources, Animals and Environment (DAFNAE), University of Padova, Padova, Italy
- 5Institute of Marine Science, National Research Council, Venezia, Italy
Saltwater intrusion in coastal aquifers is a global problem recently worsened by anthropogenic activities (e.g., aquifer overexploitation, hydraulic reclamation and drainage of low-lying areas) and climate change effects (e.g., severe droughts, sea level rise) that contribute to reduce groundwater natural recharge, water quality, and agricultural production. Many low-lying coastal plains facing the Adriatic Sea are strongly affected by saltwater intrusion with serious consequences on agricultural activities and tourism that may become dramatic in a relatively short time due to climate change. In this framework, this work aims to identify monitoring strategies to characterize the process of saltwater intrusion under the effects of climate change and recommend appropriate countermeasures in two Adriatic low-lying coastal plain: south of the Venice Lagoon (north-eastern Italy), and at the Neretva River mouth (south-eastern Croatia).
Geomorphologic, stratigraphic, hydrogeologic, and agricultural data were collected to characterize the aquifer system at both sites and assess the effects of seawater intrusion on agricultural productivity. Saltwater intrusion was monitored and analysed through monitoring systems that provide qualitative and quantitative information on the processes influencing groundwater and surface water dynamics within the two coastal systems. Moreover, laboratory physical models were developed to serve as benchmarks for the numerical models used to simulate the field results. Numerical modelling reliably implements boundary and initial conditions defined in-situ on both sites, simulates existing states, specifies different scenarios, and predicts salinization dynamic changes caused by climate changes.
The results of the research activities include the development of specific tools for the management of agriculture-related activities and freshwater resources in coastal areas including vulnerability assessment, mitigation plans, and countermeasures against salt contamination. These results were obtained by integrating the findings gained on both sites, considering differences and peculiarities of the specific areas that are representative of many low-lying plains located on both sides of the Adriatic coast.
This study has been funded by the contribution from the EU cofinancing and the Interreg Italy–Croatia Cross Border Collaboration (CBC) Programme 2014–2020 (Priority Axes: Safety and Resilience) through the European Regional Development Fund as a part of the projects MoST (AID: 10047742) and SeCure (AID: 10419304).
How to cite: Cosma, M., Zancanaro, E., Aljinović, I., Morari, F., Srzić, V., Teatini, P., Tosi, L., Bergamasco, A., Botto, A., Camporese, M., Cavallina, C., Da Lio, C., Donnici, S., Lovrinović, I., Racetin, I., Zaggia, L., Zoccarato, C., and Salandin, P.: Approaches and methodologies to monitor and mitigate saltwater intrusion in the Adriatic coastal plains, EGU General Assembly 2023, Vienna, Austria, 24–28 Apr 2023, EGU23-12125, https://doi.org/10.5194/egusphere-egu23-12125, 2023.