References

1. FAO, Climate Change, Water and Food Security, FAO Water Reports 36, Rome, 2011.
2. D. Bilalis, P.E. Kamariari, A. Karkanis, A. Efthimiadou, A.A. Zorpas, I. Kakabouki, Energy inputs, output and productivity in organic and conventional maize and tomato production, under Mediterranean conditions, Notulae Botanicae Horti Agrobotanici Cluj Napoca, 41 (2013) 1–5.
3. K.K. Tanji, N.C. Kielen, Agricultural Drainage Water Management in Arid and Semi-Arid Areas, FAO Irrigation and Drainage Paper 61, FAO, Rome, 2002.
4. B.J. Hipólito-Valencia, F.W. Mosqueda-Jiménez, J. Barajas-Fernández, J.M. Ponce-Ortega, Incorporating a seawater desalination scheme in the optimal water use in agricultural activities, Agric. Water Manage., 244 (2021) 106552, doi: 10.1016/j.agwat.2020.106552.
5. EEA, Crop Water Demand, European Environment Agency, Copenhagen, 2016.
6. B.E. Jiménez Cisneros, T. Oki, N.W. Arnell, G. Benito, J.G. Cogley, P. Döll, T. Jiang, S.S. Mwakalila, Impacts, Adaptation, and Vulnerability, C.B. Field, V.R. Barros, D.J. Dokken, K.J. Mach, M.D. Mastrandrea, T.E. Bilir, M. Chatterjee, K.L. Ebi, Y.O. Estrada, R.C. Genova, B. Girma, E.S. Kissel, A.N. Levy, S. MacCracken, P.R. Mastrandrea, L.L. White, Eds., Part A: Global and Sectoral Aspects, Cambridge University Press, Cambridge, 2014, pp. 229–269.
7. M. Tsangas, I. Gavriel, M. Doula, F. Xeni, A.A. Zorpas, Life cycle analysis in the framework of agricultural strategic development planning in the Balkan region, Sustainability, 12 (2020) 1813, doi: 10.3390/su12051813.
8. A.A. Zorpas, M. Drtil, K. Chryso, I. Voukkali, P. Samaras, Operation description and physicochemical characteristics of influent, effluent and the tertiary treatment from a sewage treatment plant of the Eastern Region of Cyprus under warm climates conditions. A seven-year project, Desal. Water Treat., 22 (2010) 244–257.
9. A.A. Zorpas, C. Coumi, M. Drtil, I. Voukkali, Municipal sewage sludge characteristics and waste water treatment plant effectiveness under warm climate conditions, Desal. Water Treat., 36 (2011) 319–333.
10. A.A. Zorpas, I. Voukkali, P. Loizia, Proposed treatment applicable scenario for the treatment of domestic sewage sludge which is produced from a sewage treatment plant under warm climates conditions, Desal. Water Treat., 51 (2013) 3081–3089.
11. M. Hallack-Alegría, D.J. Watkins, Annual and warm season drought intensity-duration-frequency analysis for Sonora, Mexico, J. Clim., 20 (2006) 1897–1909.
12. N.K. Khanzada, S. Jamal Khan, P.A. Davies, Performance evaluation of reverse osmosis (RO) pre-treatment technologies for in-land brackish water treatment, Desalination, 406 (2017) 44–50.
13. A. Trapote, J.F. Roca, J. Melgarejo, Azudes y acueductos del sistema de riego tradicional de la Vega Baja del Segura (Alicante, España), Invest. Geogr., 63 (2015) 143–160.
14. J.D. Oster, S.R. Grattan, Drainage water reuse, Irrig. Drain. Syst., 16 (2002) 297–310.
15. FAO, Water Desalination for Agricultural Applications, Land and Water Discussion Paper 5, Rome, 2006.
16. D. Zarzo, E. Campos, P. Terrero, Spanish experience in desalination for agriculture, Desal. Water Treat., 51 (2012) 1–14.
17. H.A. Talaat, S.R. Ahmed, Treatment of agricultural drainage water: technological schemes and financial indicators, Desalination, 204 (2007) 102–112.
18. R.W. Lee, J. Glater, Y. Cohen, C. Martin, K. Kovac, M.N. Milobar, D.W. Bartel, Low-pressure RO membrane desalination of agricultural drainage water, Desalination, 155 (2003) 109–120.
19. M.H. Sorour, N.M.H. El Defrawy, H.F. Shaalan, Treatment of agricultural drainage water via lagoon/reverse osmosis system, Desalination, 152 (2002) 359–366.
20. W. Suwaileh, D. Johnson, N. Hilal, Membrane desalination and water re-use for agriculture: state of the art and future oulook, Desalination, 49 (2020) 114559, doi: 10.1016/j.desal.2020.114559.
21. I.P. Abrol, J.S.P. Yadav, F.I. Massud, Salt-Affected Soils and Their Management, FAO Soils Bulletin 39, Rome, 1988.
22. F. Sheng, C. Xiuling, Using shallow saline groundwater for irrigation and regulating for soil salt-water regime, Irrig. Drain. Syst., 11 (1997) 1–14.
23. J.J. Escolano, J. Navarro Pedreño, I. Gómez Lucas, M.B. Almendro Candel, A.A. Zorpas, Decreased Organic Carbon Associated With Land Management in Mediterranean Environments, M.Á. Muñoz, R. Zornoza, Eds., Soil Management and Climate Change: Effects on Organic Carbon, Nitrogen Dynamics and Greenhouse Gas Emissions, Academic Press Books – Elsevier, Cambridge, Massachusetts, 2018, pp. 16–29.
24. Z. Liu, D. Zhang, J. Ping, Y. Han, Q. Cai, Applicability evaluation of groundwater in the People’s Victory Canal Irrigation Area, China, Desal. Water Treat., 168 (2019) 207–215.
25. M.H. Sorour, A.G. Abulnour, H.A. Tallat, Desalination of agricultural drainage water, Desalination, 86 (1992) 63–75.
26. A.G. Abulnour, M.H. Sorour, H.A. Talaat, Comparative economics for desalting of agricultural drainage water (ADW), Desalination, 152 (2002) 353–357.
27. L.T.A. Salama, K.Z. Addalla, Design and analysis of a solar photovoltaic powered seawater reverse osmosis plant in the southern region of the Gaza Strip, Desal. Water Treat., 143 (2019) 96–101.
28. A. Tal, Addresing desalination’s carbon footprint: the Israeli experience, Water, 10 (2018) 197, doi: 10.3390/w10020197.
29. S.G. Salinas-Rodríguez, J.C. Schippers, M.D. Kennedy, Chapter 1 – The Process of Reverse Osmosis, S. Burn, S. Gray, Eds., Efficient Desalination by Reverse Osmosis: A Guide to RO Practice, IWA, London, 2016, pp. 5–25.
30. N.C. Darre, G.S. Toor, Desalination of water: a review, Curr. Pollut. Rep., 4 (2018) 104–111.
31. J.A. Medina, Desalación de Aguas Salobres y de Mar. Osmosis Inversa, Mundi-Prensa, Madrid, 2000.
32. B.E. Smith, Desalting and ground water management in the San Joaquin Valley, California, Desalination, 87 (1992) 151–174.
33. E. Guler, E. Onkal, M. Clen, E. Sari, Cost analysis of seawater desalination using an integrated reverse osmosis system on a cruise ship, Global NEST J., 1 (2015) 389–396.
34. A. Aghakhani, S.F. Mousavi, B. Mostafazadeh-Fard, R. Rostamian, M. Seraji, Application of some combined adsorbents to remove salinity parameters from drainage water, Desalination, 275 (2011) 217–223.
35. A.F. Mashaly, A.A. Alazba, A.M. Al-Awaadh, M.A. Mattarb, Area determination of solar desalination system for irrigating crops in greenhouses using different quality feed water, Agric. Water Manage., 154 (2015) 1–10.
36. A.A. Zorpas, Strategy development in the framework of waste management, Sci. Total Environ., 716 (2020) 137088, doi: 10.1016/j.scitotenv.2020.137088.
37. P. Loizia, N. Neofytou, A.A. Zorpas, The concept of circular economy in food waste management for the optimization of energy production through UASB reactor, Environ. Sci. Pollut. Res., 26 (2019) 14766–14773.
38. P. Loizia, I. Voukkali, A.A. Zorpas, J. Navarro-Pedreño, G. Chatziparaskeva, V.J. Inglezakis, I. Vardopoulos, Measuring environmental performance in the framework of waste strategy development, Sci. Total Environ., 753 (2021) 141974, doi: 10.1016/j.scitotenv.2020.141974.
39. J. Aparicio, L. Candela, O. Alfranca, Social and private cots of water for irrigation: the small desalination plant in San Vicente del Raspeig, Spain, Desalination, 439 (2018) 102–107.
40. M. Nasr, H. Zahran, Using of pH as a tool to predict salinity of groundwater for irrigation purpose using artificial neural network, Egypt. J. Aquat. Res., 40 (2014) 111–115.
41. R. Hashimoto, Improved Conductivity Analysis in Desalination Processes, Water Wastewater Asia, (2015) 40–42.
42. IUSS Working Group WRB, World Reference Base for Soil Resources 2014, Update 2015 International Soil Classification System for Naming Soils and Relating Legends for Soil Maps, World Soil Resources Reports 106, Rome, 2015.
43. A. Gil, G. Canales, Consolidación de dominios en las Pías Fundaciones del cardenal Belluga (Bajo Segura), Invest. Geogr., 5 (1987) 7–26.
44. K. Fleming, P. Johnston, D. Zwartz, Y. Yokoyama, K. Lambeck, J. Chapell, Refining the eustatic sea-level curve since the Last Glacial Maximum using far and intermediated-fieldsites, Earth Planet. Sci. Lett., 163 (1998) 327–342.
45. J.E. Tent-Manclús, Cambio de la línea de costa en el Bajo Segura (Sur de Alicante) en los últimos 15000 años, Estudios Geogr., 74 (2013) 683–702.
46. A.M. Blázquez, J. Usera, Palaeoenvironments and quaternary foraminifera in the Elx coastal lagoon (Alicante,Spain), Quat. Int., 221 (2010) 68–90.
47. K. Ghodeif, T. Grischelk, R. Bartak, R. Wahaab, J. Herlitzius, Potential of river bank filtration (RBF) in Egypt, Environ. Earth Sci., 75 (2016) 671, doi: 10.1007/s12665-016-5454-3.
48. APHA, AWWA, and WEF, Standard Methods for the Examination of Water and Wastewater, 21st ed., American Public Health Association/American Water Works Association/Water Environment Federation, Washington DC, 2005.
49. A.G. Vlyssides, M. Loizidou, A.A. Zorpas, Characteristics of solid residues from olive oil processing as a bulking material for co-composting with industrial wastewater, J. Environ. Sci. Health., Part A, 34 (1999) 737–748.
50. J.P. Michaud, M. Wierenga, Estimating Discharge and Stream Flows. A Guide for Sand and Gravel Operators, Ecology Publication 05-10-070, Washington State Department of Ecology, 2005.
51. R. Ayers, D. Westcot, Water Quality for Agriculture, Irrigation and Drainage Paper 29, Rome, 1994.
52. M. Thompson, D. Brandes, A. Kney, Using electronic conductivity and hardness data for rapid assessment of stream water quality, J. Environ. Manage., 104 (2012) 152–157.
53. R.H. Tyler, T.P. Boyer, T. Minami, M.M. Zweng, J.R. Reagan, Electrical conductivity of the global ocean, Earth Planet. Space, 69 (2017) 156.
54. M. Qasim, M. Bdrelzaman, N.D. Darwish, N.A. Darwish, Reverse osmosis desalination: a state-of-the-art review, Desalination, 459 (2019) 59–104.
55. T. Scherer, M. Meehan, Using Electrical Conductivity and Total Dissolved Solids Meters to Field Test Water Quality, WQ1923, North Dakota State University, Fargo ND, 2019.
56. J. Thompson, A. Rahardianto, H. Gu, M. Uchymiak, A. Bartman, M. Hedrick, D. Lara, J. Cooper, J. Faria, P.D. Christofides, Y. Cohen, Rapid field assessment of RO desalination of brackish agricultural drainage water, Water Res., 47 (2013) 2649–2660.
57. R.A.O. Barron, G. Hodgson, D. Smith, E. Qureshi, D. McFarlane, E. Campos, D. Zarzo, Feasibility assessment of desalination application in Australian traditional agriculture, Desalination, 364 (2015) 33–45.
58. E. Jones, M. Qadir, M.T.H. van Vliet, V. Smakhtin, S. Kang, The state of desalination and brine production: a global outlook, Sci. Total Environ., 657 (2019) 1343–1356.
59. N.A. Ahmad, P.S. Goh, L.T. Yogarathinam, A.K. Zulhairun, A.F. Ismail, Current advances in membrane technologies for produced water desalination, Desalination, 493 (2020) 114643, doi: 10.1016/j.desal.2020.114643.
60. S. Bhojwani, K. Topolski, R. Mukherjee, D. Sengupta, M.M. El-Halgawi, Technology review and data analysis for cost assessment of water treatment systems, Sci. Total Environ., 651 (2019) 2749–2761.
61. A. Loya-Fernández, L.M. Ferrero-Vicente, C. Marco-Méndez, E. Martínez-García, J. Zubcoff, J.L. Sánchez-Lizaso, Comparing four mixing zone models with brine discharge measurements from a reverse osmosis desalination plant in Spain, Desalination, 286 (2012) 217–224.
62. U. Caldera, C. Breyer, Assessing the potential for renewable energy powered desalination for the global irrigation sector, Sci. Total Environ., 694 (2019) 133598, doi: 10.1016/j. scitotenv.2019.133598.
63. K. Elsaid, M. Kamil, E.T. Sayed, M.A. Addelkareem, T. Wilberforce, A. Olabi, Environmental impact of desalination technologies: a review, Sci. Total Environ., 748 (2020) 141528, doi: 10.1016/j.scitotenv.2020.141528.
64. J. Álvarez-Rogel, G.G. Barberá, B. Maxwell, M. Guerrero-Brotons, C. Díaz-García, J.J. Martínez-Sánchez, A. Sallent, J. Martínez-Ródenas, M.N. González-Alcaraz, F.J. Jiménez-Cárceles, C. Tercero, R. Gómez, The case of Mar Menor eutrophication: state of the art and description of tested Nature-Based Solutions, Ecol. Eng., 158 (2020) 106086, doi: 10.1016/j. ecoleng.2020.106086.
65. N. Nabbou, M. Belhachemi, M. Boumelik, T. Merzougui, D. Lahcene, Y. Harek, A.A. Zorpas, M. Jeguirim, Removal of fluoride from groundwater using natural clay (kaolinite): optimization of adsorption conditions, C.R. Chim., 22 (2019) 105–112.