References

  1. V. Bhakar, D.N.S. Hemanth Kumar, N.K. Sai, K. Singh Sangwan, S. Raghuvanshi, Life cycle assessment of filtration systems of reverse osmosis units: a case study of a university campus, Procedia CIRP, 40 (2016) 268–273.
  2. M.S. Mohsen, B. Akash, A. Abu Abdo, O. Akash, Energy Option for Water Desalination in UAE, The International Conference on Sustainable Energy Information Technology (SEIT 2016), Procedia Science, 83 (2016) 894–901.
  3. A. Alkaisi, R. Mossad, A. Sharifian-Barforoush, A Review of the Water Desalination Systems Integrated with Renewable Energy, 1st International Conference on Energy and Power, ICEP 2016, 14–16 December 2016, RMIT University, Melbourne, Australia, Energy Procedia, Vol. 110, 2017, pp. 268–274.
  4. G. Micale, A. Cipollina, L. Rizzuti, Seawater Desalination for Freshwater Production, Seawater Desalination Conventional and Renewable Energy Processes, Vol. 1, 2009, pp. 1–15.
  5. S.M. Rao, P. Mamatha, Water quality in sustainable water management, Current Sci., 87 (2004) 942–947.
  6. M. Methnani, Influence of fuel costs on seawater desalination options, Desalination, 205 (2007) 332–339.
  7. M. Sarai Atab, A.J. Smallbone, A.P. Roskilly, An operational and economic study of a reverse osmosis desalination system for potable water and land irrigation, Desalination, 397 (2016) 174–184.
  8. B. Peñate, L. García-Rodríguez, Current trends and future prospects in the design of seawater reverse osmosis desalination technology, Desalination, 284 (2012) 1–8.
  9. D.E. Sachit, J.N. Veenstra, Analysis of reverse osmosis membrane performance during desalination of simulated brackish surface waters, J. Membr. Sci., 453 (2014) 136–154.
  10. X. Zheng, D. Chen, Q. Wang, Z. Zhang, Seawater desalination in China: retrospect and prospect, Chem. Eng. J., 24 (2014) 404–413.
  11. S. Lattemann, T. Höpner, Environmental impact and impact assessment of seawater desalination, Desalination, 220 (2008) 1–15.
  12. N. Ghaffour, T.M. Missimer, G.L. Amy, Technical review and evaluation of the economics of water desalination: current and future challenges for better water supply sustainability, Desalination, 309 (2013) 197–207.
  13. K. Zotalis, E.G. Dialynas, N. Mamassis, A.N. Angelakis, Desalination technologies: hellenic experience, Water, 6 (2014) 1134.
  14. Global Water Intelligence and International Desalination Association, IDA Desalination Yearbook 2016−2017, Media Analytics Ltd., Oxford, 2016.
  15. C.-D. Dumitru, A. Gligoi, C. Enachescu, Solar photovoltaic Energy Production Forecast Using Neural Networks, 9th International Conference Interdisciplinarity in Engineering, INTER-ENG 2015, 8–9 October, Tirgu-Mures, Romania, 2016.
  16. X. Zhang, J. Shen, T. Yang, L. Tang, Y. Wu, S. Pan, J. Wu, P. Xu, Assessment of the effectiveness of investment strategy in solar photovoltaic (PV) energy sector: a case study, Energy Procedia, 105 (2017) 2977–2982.
  17. M.A. Mahmud, H.R. Pota, M.J. Hossain, Dynamic stability of three-phase grid-connected photovoltaic system using zero dynamic design approach, IEEE J. Photovolt., 2 (2012) 564–571.
  18. R. Nazir, K. Kanada, Syafii, P. Coveria, Optimization active and reactive power flow for PV connected to grid system using Newton Raphson method, Energy Procedia, 68 (2015) 77–86.
  19. M. Gratzel, Photovoltaic and photoelectron chemical conversion of solar energy, Philos. Trans. R. Soc. A-Math. Phys. Eng. Sci., 365 (2007) 993–1005.
  20. US Department of Energy (USDE), Energy Efficiency and Renewable Energy: Photovoltaics, US Department of Energy, 2010. Available from: http://www.eere.energy.gov/basics/renewable_energy/photovoltaics.html.
  21. A.K. Shukla, K. Sudhakar, P. Baredar, Simulation and performance analysis of 110 kWp grid-connected photovoltaic system for residential building in India: a comparative analysis of various PV technology, Energy Rep., 2 (2016) 82–88.
  22. A. Singh, P. Baredar, Techno-economic assessment of a solar PV, fuel cell, and biomass gasifier hybrid energy system, Energy Rep., 2 (2016) 254–260.
  23. Palestinian Central Bureau of Statistics (PCBS), Preliminary Census Results, Ramallah – Palestine, 2017.
  24. Palestinian Central Bureau of Statistic (PCBS), Statistical Report on Jerusalem, Ramallah-Palestine, 2017.
  25. Coastal Municipal Water Utility (CMWU), Annual Report on Water Status in the Gaza Strip, 2011.
  26. Palestinian Water Authority (PWA), Water Demand Management Plan and its Implication of the Water Resources Deficit on Gaza Strip, Gaza Strip, Palestine, 2012.
  27. Palestinian Water Authority (PWA), Status Report of Water Resources in the Occupied State of Palestine, Final Report, October 2013.
  28. Palestinian Water Authority (PWA), Status Report of Water Resources in the Gaza Strip, Final Report, Gaza – Palestine, 2016.
  29. United Nations Relief and Works Agency for Palestine Refugees in the Near East (UNRWA), Gaza in 2020, UNRWA Operational Response, 2013.
  30. World Bank, Securing Energy for Development in West Bank and Gaza, Summary Report, 2017.
  31. The Gaza Electricity Distribution Corporation (GEDCo), Headquarters, Technical Department, 2018.
  32. Palestinian Energy Authority (PEA), Atlas of Solar Resources of the State of Palestine, Ramallah – Palestine, 2015.
  33. G. Howard, J. Bartram, Domestic Water Quantity, Service, Level and Health, World Health Organization (WHO), Geneva, 2003.
  34. D. Heimiller, Simple Photovoltaic Economic Calculations– National Renewable Energy Laboratory, Task 3 deliverable, NARUC, 2010.