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Irrigation reuse of urban treated wastewater: A qualitative analysis to support crop production in Campania

DOI
https://doi.org/10.3280/ecag2025oa20797
Submitted
agosto 1, 2025
Published
2025-11-27

Abstract

The sustainability of the agricultural sector is closely linked to the ability of territorial system to effectively address the challenges of water resource management in the context of climate change. The reuse of treated wastewater is increasingly recognized as a key strategy for ensuring a sustainable water supply in agriculture. This study proposes an innovative methodological approach aimed at identifying the Utilised Agricultural Area (UAA) potentially irrigable with treated wastewater, with particular attention to high value crops certified as PDO (Protected Designation of Origin) and PGI (Protected Geographical Indication) in the Campania region. The methodology is based on the integration of data from three main sources: SIGRIAN, for mapping irrigated areas; EEA/SINTAI, for classifying wastewater treatment plants; and AGEA, for identifying land use in irrigated areas. This approach enables the association, in accordance with Regulation (EU) 2020/741, of the water quality class required for each crop with that one potentially available from wastewater treatment plants, also taking into account the existence of suitable distribution infrastructures. The results of the analysis highlight that the proposed methodology, applied to agricultural sector in Campania, with a focus on high-quality production, can effectively guide public policies in promoting targeted infrastructure investments. These investments aim to protect areas most vulnerable to drought and support high value crops, particularly certified ones, through the adoption of advanced technological solutions and integrated water resource planning, which are key to ensuring the resilience and long-term prosperity of the regional agricultural sector.

References

  1. Ayers, R. S., & Westcot, D. W. (1985). Water quality for agriculture. FAO, 29, 174.
  2. Berbel, J., Mesa‐Pérez, E., & Simón, P. (2023). Challenges for Circular Economy under the EU 2020/741 Wastewater Reuse Regulation. Global Challenges, 7(7), 2200232. Doi: 10.1002/gch2.202200232.
  3. Birol, E., Koundouri, P., & Kountouris, Y. (2010). Assessing the economic viability of alternative water resources in water-scarce regions: Combining economic valuation, cost-benefit analysis and discounting. Ecological Economics, 69(4), 839-847. Doi: 10.1016/j.ecolecon.2009.10.008.
  4. Blanco-Gutiérrez, I., & et al. (2021). RECLAMO: Unlocking the potential of wastewater reuse for agricultural irrigation in Spain. Research Ideas and Outcomes, 7.
  5. Bordbar, M., Busico, G., Stevenazzi, S., & Mastrocicco, M. (2025). How do hydrogeological and socio-economic parameters influence the likelihood of NO3 − pollution and Cl − salinization? An application within the Campania region (Italy). Natural Hazards. Doi: 10.1007/s11069-025-07300-5.
  6. Braca, G., Bussettini, M., Ducci, D., Lastoria, B., & Mariani, S. (2019). Evaluation of national and regional groundwater resources under climate change scenarios using a GIS-based water budget procedure. Rendiconti Lincei. Scienze Fisiche e Naturali, 30(1), 109-123. Doi: 10.1007/s12210-018-00757-6.
  7. Burak, S., & Margat, J. (2016). Water Management in the Mediterranean Region: Concepts and Policies. Water Resources Management, 30(15), 5779-5797. Doi: 10.1007/s11269-016-1389-4.
  8. Busico, G., Kazakis, N., Colombani, N., Mastrocicco, M., Voudouris, K., & Tedesco, D. (2017). A modified SINTACS method for groundwater vulnerability and pollution risk assessment in highly anthropized regions based on NO3 − and SO42 − concentrations. Science of The Total Environment, 609, 1512-1523. Doi: 10.1016/j.scitotenv.2017.07.257.
  9. Colella, M., Ripa, M., Cocozza, A., Panfilo, C., & Ulgiati, S. (2021). Challenges and opportunities for more efficient water use and circular wastewater management. The case of Campania Region, Italy. Journal of Environmental Management, 297, 113171. Doi: 10.1016/j.jenvman.2021.113171.
  10. Cusano, D., Allocca, V., Fusco, F., Tufano, R., & De Vita, P. (2019). Multi-Scale Assessment Of Groundwater Vulnerability To Pollution: Study Cases from Campania Region (Southern Italy). Italian Journal of Engineering Geology and Environment, 3, 19-24. Doi: 10.4408/IJEGE.2019-01.S-03.
  11. D’Alicandro, N. (2024). Il sostegno del piano strategico della pac 2023-2027 agli investimenti in infrastrutture. Una prima analisi delle principali scelte regionali - Dicembre 2024. Rete Rurale Nazionale.
  12. Drei, P., Mancuso, G., Lavrnić, S., Maffettone, R., Spizzirri, M., Merluzzi, L., Mastrantonio, A., Burla, P., & Toscano, A. (2025). A novel methodology to develop EU water reuse risk management plan in agricultural water distribution networks and crop irrigation systems. Water Research X, 28, 100395. Doi: 10.1016/j.wroa.2025.100395.
  13. EEA (2020). Water and agriculture: Towards sustainable solutions – EEA Report No 17/2020 [Publication]. -- https://www.eea.europa.eu/publications/water-andagriculture-towards-sustainable-solutions.
  14. EEA (2021). Water and agriculture: Towards sustainable solutions. EEA Report No 17/2020.
  15. Farabegoli, G. (2023). Il riutilizzo delle acque reflue affinate: L’Italia è pronta a recepire il regolamento (UE) 2020/741? Ingegneria dell’Ambiente, 10(1), 1. Doi: 10.32024/ida.v10i1.449.
  16. Ferrigno, M., Manganiello, V., Pergamo, R., Ruberto, M., Furini, M., Folino, L. A., & Crisponi, N. (2023). Politiche e approcci per la pianificazione e il monitoraggio degli interventi infrastrutturali irrigui per il riutilizzo delle acque reflue depurate in agricoltura. Proceeding Ecomondo.
  17. Ferrigno, M., & Zucaro, R. (2023). Le infrastrutture irrigue a sostegno dell’agricoltura italiana. In Zumpano, Catia (Ed.), Infrastrutture rurali e sviluppo territoriale. Politiche a confronto.
  18. Fondazione Qualivita (2025). Fondazione Qualivita: Osservatorio Campania. Fondazione Qualivita. -- https://www.qualivita.it/osservatorio/osservatorio-r15/.
  19. Fondazione Utilitatis (2024). Blue Book 2024 – Servizio Idrico Integrato e Filiera Estesa dell’acqua. -- https://utilitatis.org/my-product/blue-book-2024/.
  20. Hamam, M., Pergamo, R., Manganiello, V., & Ferrigno, M. (2024). Agricultural Wastewater Reuse as a Circular Economy Model: Future Scenarios Considering Reg. (EU) 2020/741. Water, 16(24), 3638. Doi: 10.3390/w16243638.
  21. Ingrao, C., Strippoli, R., Lagioia, G., & Huisingh, D. (2023). Water scarcity in agriculture: An overview of causes, impacts and approaches for reducing the risks. Heliyon, 9(8), e18507. Doi: 10.1016/j.heliyon.2023.e18507.
  22. ISMEA, & Fondazione Qualivita (2023). Rapporto ISMEA - Qualivita 2023 sulle produzioni agroalimentari e vitivinicole italiane dop, igp e stg - xxi edizione.
  23. Koundouri, P., Alamanos, A., Plataniotis, A., Stavridis, C., Perifanos, K., & Devves, S. (2024). Assessing the sustainability of the European Green Deal and its interlinkages with the SDGs. Npj Climate Action, 3(1), 23. Doi: 10.1038/s44168-024-00104-6.
  24. Leff, B., Ramankutty, N., & Foley, J. A. (2004). Geographic distribution of major crops across the world. Global Biogeochemical Cycles, 18(1). Doi: 10.1029/2003GB002108.
  25. Maffettone, R., Manoli, K., Drei, P., Cacciatori, C., Bellini, R., & Gawlik, B. M. (2024). Water Reuse in the European Union: Risk Management Approach According to the Regulation (EU) 2020/741. In: M. Minella, A. Bianco Prevot, & V. Maurino (Eds.), Water Reuse and Unconventional Water Resources (Vol. 113, pp. 413-442). Springer Nature Switzerland. Doi: 10.1007/978-3-031-67739-7_17.
  26. Mancuso, G., Parlato, M. C. M., Lavrnić, S., Toscano, A., & Valenti, F. (2022). GISBased Assessment of the Potential for Treated Wastewater Reuse in Agricultural Irrigation: A Case Study in Northern Italy. Sustainability, 14(15), 9364. Doi: 10.3390/su14159364.
  27. Mastrocicco, M., Gervasio, M. P., Busico, G., & Colombani, N. (2021). Natural and anthropogenic factors driving groundwater resources salinization for agriculture use in the Campania plains (Southern Italy). Science of The Total Environment, 758, 144033. Doi: 10.1016/j.scitotenv.2020.144033.
  28. McLennan, C., Rudi, G., Altchenko, Y., & Ait-Mouheb, N. (2024). Will the European Regulation for water reuse for agricultural irrigation foster this practice in the European Union?. Water Reuse, 14(2), 115-135. Doi: 10.2166/wrd.2024.012.
  29. Mendicino, G., Senatore, A., & Versace, P. (2008). Water Resources Management in Agriculture under Drought and Water Shortage Conditions: A Case Study in Southern Italy. European Water, 23/24, 41-56.
  30. Paranychianakis, N., Salgot, M., Snyder, S., & Angelakis, A. (2015). Water Reuse in EU-States: Necessity for Uniform Criteria to Mitigate Human and Environmental Risks. Critical Reviews in Environmental Science and Technology, (in press). Doi: 10.1080/10643389.2014.955629.
  31. Pedrero, F., Kalavrouziotis, I., Alarcón, J. J., Koukoulakis, P., & Asano, T. (2010). Use of treated municipal wastewater in irrigated agriculture – Review of some practices in Spain and Greece. Agricultural Water Management, 97(9), 1233-1241. Doi: 10.1016/j.agwat.2010.03.003.
  32. Ramm, K., Pizza, F., Scibilia, G., & Binetti, R. (2024). An Update on Water Reuse in the European Union Considering the Regulation 2020/741. In: Minella, M., Bianco Prevot, A., & Maurino, V. (Eds.), Water Reuse and Unconventional Water Resources (Vol. 113, pp. 591-615). Springer Nature Switzerland. Doi: 10.1007/978-3-031-67739-7_25.
  33. Scanlon, B. R., Fakhreddine, S., Rateb, A., De Graaf, I., Famiglietti, J., Gleeson, T., Grafton, R. Q., Jobbagy, E., Kebede, S., Kolusu, S. R., Konikow, L. F., Long, D., Mekonnen, M., Schmied, H. M., Mukherjee, A., MacDonald, A., Reedy, R. C., Shamsudduha, M., Simmons, C. T., … Zheng, C. (2023). Global water resources and the role of groundwater in a resilient water future. Nature Reviews Earth & Environment, 4(2), 87-101. Doi: 10.1038/s43017-022-00378-6.
  34. SNPA – Sistema nazionale protezione ambiente (2024). Rapporto Ambiente – SNPA. Edizione 2023. -- https://www.snpambiente.it/snpa/rapporto-ambiente-snpaedizione-2023/.
  35. United Nations (2017). The United Nations world water development Report 2017 – Wastewater, the Untapped Resource. -- https://unesdoc.unesco.org/ark:/48223/pf0000247153.

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