1. S. Zhou, Y. Guo, X. Mu, S. Shen, Effect of design parameters on thermodynamic losses of the heat transfer process in LT-MEE desalination plant, Desalination, 375 (2015) 40–47.
  2. K.M. Bataineh, Multi-effect desalination plant combined with thermal compressor driven by steam generated by solar energy, Desalination, 385 (2016) 39–52.
  3. Q. Chun-hua, F. Hou-jun, L. Qing-chun, X. Yu-lei, L. Nan, Performance study of a pilot-scale low-temperature multi-effect desalination plant, Appl. Energy, 135 (2014) 415–422.
  4. M.T. Mazini, A. Yazdizadeh, M.H. Ramezani, Dynamic modeling of multi-effect desalination with thermal vapor compressor plant, Desalination, 353 (2014) 98–108.
  5. A.D. Khawaji, I.K. Kutubkhanah, J.M. Wie, Advances in seawater desalination technologies, Desalination, 221 (2008) 48–52.
  6. I.C. Watson, and O.J. Morin, Desalination and Water Purification Research and Development Program. Desalting Handbook for Planners (2003) Report No. 72. Florida.
  7. N. Bouzayani, N. Galanis, J. Orfi, Thermodynamic analysis of combined electric power generation and water desalination plants, Appl. Thermal Eng., 29 (2009) 624–633.
  8. A.S. Nafey, and M.A. Sharaf, Combined solar organic Rankine cycle with reverse osmosis desalination process: Energy, exergy, and cost evaluations, Renew. Energy, 35 (2010) 2571– 2580.
  9. A.A. Alawadhi, Regional Report on Desalination-GCC Countries in: Proc. IDA World Congress on Desalination and Water Reuse, 2002, Manama. Bahrain, pp. 8–13.
  10. D. Geng, Y. Du, R. Yang, Performance analysis of an organic Rankine cycle for a reverse osmosis desalination system using zeotropic mixtures, Desalination, 381 (2016) 38–46.
  11. S.R. Hosseini, M. Amidpour, A. Behbahaninia, Thermoeconomic analysis with reliability consideration of a combined power and multi stage flash desalination plant, Desalination, 278 (2011) 424–433.
  12. R. Deng, L. Xie, H. Lin, J. Liu, W. Han, Integration of thermal energy and seawater desalination, Energy, 35 (2010) 4368–4374.
  13. S.P. Agashichev, and K.N. Lootah, Influence of temperature and permeate recovery on energy consumption of a reverse osmosis system, Desalination, 154 (2003) 253–266.
  14. B.A. Qureshi, and S.M. Zubair, Exergetic efficiency of NF, RO and EDR desalination plants, Desalination, 378 (2016) 92–99.
  15. C. Li, S. Besarati, Y. Goswami, E. Stefanakos, H. Chen, Reverse osmosis desalination driven by low temperature supercritical organic rankine cycle, Appl. Energy, 102 (2013) 1071–1080.
  16. A. Altaee, and A. Sharif, Pressure retarded osmosis: advancement in the process applications or power generation and desalination, Desalination, 356(15) (2015) 31–46.
  17. O.K. Buros, The ABCs of Desalting. 2nd ed., International Desalination Association, Topsfield, MA, USA, 2003.
  18. A. Altaee, G.J. Millar, G. Zaragoza, Integration and optimization of pressure retarded osmosis with reverse osmosis for power generation and high efficiency desalination, Energy, 103 (2016) 110–118.
  19. V. Gadhamshetty, V.G. Gude, N. Nirmalakhandan, Thermal energy storage system for energy conservation and water desalination in power plants, Energy, 66 (2014) 938–949.
  20. A.H. Araghi, M. Khiadani, K. Hooman, A novel vacuum discharge thermal energy combined desalination and power generation system utilizing R290/R600a, Energy, 98 (2016) 215–224.
  21. Seyed Reza Hosseini, Majid Amidpour, Seyed Ehsan Shakib, Cost optimization of a combined power and water desalination plant with exergetic, environment and reliability consideration, Desalination, 285 (2012) 123–130.
  22. W. Lianying, H. Yangdong, G. Congjie, Optimum design of cogeneration for power and desalination to satisfy the demand of water and power, Desalination, 324 (2013) 111–117.
  23. G. Kosmadakis, D. Manolakos, S. Kyritsis, G. Papadakis, Design of a two stage organic Rankine cycle system for reverse osmosis desalination supplied from a steady thermal source, Desalination, 250 (2010) 323–328.
  24. M. Ameri, and M. Jorjani, Performance assessment and multi-objective optimization of an integrated organic Rankine cycle and multi-effect desalination system, Desalination, 392 (2016) 34–45.
  25. B.F. Tchanche, Gr. Lambrinos, A. Frangoudakis, G. Papadakis, Exergy analysis of micro-organic Rankine power cycles for a small scale solar driven reverse osmosis desalination system, Appl. Energy 87 (2010) 1295–1306.
  26. A. Tamburini, A. Cipollina, G. Micale, A. Piacentino, CHP (combined heat and power) retrofit for a large MED-TVC (multiple effect distillation along with thermal vapour compression) desalination plant: high efficiency assessment for different design options under the current legislative EU framework, Energy, (2016) 1–12.
  27. K.S. Maheswari, K.K Murugavel, G. Esakkimuthu, Thermal desalination using diesel engine exhaust waste heat — An experimental analysis, Desalination, 358 (2015) 94–100.
  28. C. Li, G. Kosmadakis, D. Manolakos, E. Stefanakos, G. Papadakis, D.Y. Goswami, Performance investigation of concentrating solar collectors coupled with a transcritical organic Rankine cycle for power and seawater desalination co-generation, Desalination, 318 (2013) 107–117.
  29. S. Bross, and W. Kochanowski, SWRO core hydraulic module — The right concept decides in terms of energy consumption and reliability. Part II. Advanced pressure exchanger design, Desalination, 165 (2004) 351–361.
  30. N. Bouzayani, N. Galanis, J. Orfi, Comparative study of power and water cogeneration systems, Desalination, 205 (2007) 243–253.
  31. P. Geisler, F.U. Hahnenstein, W. Krumm, T. Peters, Pressure exchange system for energy recovery in reverse osmosis plants, Desalination, 122 (1999) 151–156.
  32. W. Zhou, L. Song, T.K. Guan, A numerical study on concentration polarization and system performance of spiral wound RO membrane modules, J. Membr. Sci., 271 (2006) 38–46.
  33. A. Altaee, G. Zaragoza, S. Adel, Pressure retarded osmosis for power generation and seawater desalination: Performance analysis, Desalination, 344 (2014) 108–115.
  34. A. Date, M. Ahmadi, A. Akbarzadeh, S. Ganguly, M.S. Kumar, Experimental Performance Investigation and Case Study of Combined Desalination and Power Generation. Proceedings World Geothermal Congress, Melbourne, Australia, 2015, pp. 19–25.
  35. H. Ludwig, Hybrid systems in seawater desalination—practical design aspects, present status and development perspectives, Desalination, 164 (2004) 1–18.
  36. W. He, Y. Wang, A. Sharif, M.H. Shaheed, Thermodynamic analysis of a stand-alone reverse osmosis desalination system powered by pressure retarded osmosis, Desalination, 352 (2014) 27–37.
  37. P. Geisler, W. Krumm, T. Peters, Optimization of the energy demand of reverse osmosis with a pressure-exchange system, Desalination, 125 (1999) 167–172.
  38. A.S. Nafey, M.A. Sharaf, L. García-Rodríguez, Thermo-economic analysis of a combined solar organic Rankine cycle-reverse osmosis desalination process with different energy recovery configurations, Desalination, 261 (2010) 138–147.
  39. B. Peñate, L. García-Rodríguez, Retrofitting assessment of the Lanzarote IV seawater reverse osmosis desalination plant, Desalination, 266 (2011) 244–255.
  40. Y.C. Kim, and M. Elimelech, Potential of osmotic power generation by pressure retarded osmosis using seawater as feed solution: Analysis and experiments, J. Membr. Sci., 429 (2013) 330–337.
  41. Y. Cerci, Exergy analysis of a reverse osmosis desalination plant in California, Desalination, 142 (2002) 257–266.
  42. R. Deng, L. Xie, H. Lin, J. Liu, W. Han, Integration of thermal energy and seawater desalination, Energy, 35(11) (2010) 4368–4374.
  43. O.A. Hamed, H.A. Al-Washmi, H.A. Al-Otaibi, Thermoeconomic analysis of a power/water cogeneration plant, Energy, 31(14) (2006) 2699–2709.