Abstract
Purpose of Review
In the face of rising water demands and dwindling freshwater supplies, alternative water sources are needed. Desalination of water has become a key to helping meet increasing water needs, especially in water-stressed countries where water obtained by desalination far exceeds supplies from the freshwater sources.
Recent Findings
Recent technological advancements have enabled desalination to become more efficient and cost-competitive on a global scale. This has become possible due to the improvement in the materials used in membrane-based desalination, incorporation of energy-recovery devices to reduce electricity demands, and combining different desalination methods into hybrid designs. Further, there has been a gradual phasing-in of renewable energy sources to power desalination plants, which will help ensure the long-term sustainability of desalination. However, there are still challenges of reducing energy demands and managing waste products from the desalination to prevent adverse environmental effects.
Summary
This article reviews the history, location, components, costs, and other facets of desalination and summarizes the new technologies that are set to improve the overall efficiency of the desalination process.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ibrahim AGM, Rashad AM, Dincer I. Exergoeconomic analysis for cost optimization of a solar distillation system. Solar Energy. 2017;151:22–32.
Shahzad MW, Burhan M, Ng KC. Pushing desalination recovery to the maximum limit: membrane and thermal processes integration. Desalination. 2017;416:54–64.
Richter BD, Abell D, Bacha A, et al. Tapped out: how can cities secure their water future? Water Policy. 2013;15(3):335–63.
Rabinowitz O. Nuclear energy and desalination in Israel. Bull At Sci. 2017;72(1):32–8.
Sepehr M, Fatemi SMR, Danehkar M, Moradi AM. Application of Delphi method in site selection of desalination plants. Glob J Environ Sci Manag. 2017;3(1):89–102.
Esfahani IJ, Rashidi J, Ifaei P, Yoo C. Efficient thermal desalination technologies with renewable energy systems: a state-of-the-art review. Korean J Chem Eng. 2016;33(2):351–87.
Nair M, Kumar D. Water desalination and challenges: the Middle East perspective: a review. Desalin Water Treat. 2012;51:10–2.
Judd SJ. Membrane technology costs and me. Water Res. 2017;122:1–9.
Nriagu J, Darroudi F, Shomar B. Health effects of desalinated water: role of electrolyte disturbance in cancer development. Environ Res. 2016;150:191–204.
He W, Wang J. Feasibility study of energy storage by concentrating/desalinating water: concentrated water energy storage. Appl Energy. 2017;185(Pt. 1):872–84.
Frank H, Rahav E, Bar-Zeev E. Short-term effects of SWRO desalination brine on benthic heterotrophic microbial communities. Desalination. 2017;417:52–9.
DeNicola E, Aburizaiza OS, Siddique A, Khwaja H, Carpenter DO. Climate change and water scarcity: the case of Saudi Arabia. Ann Globe Health. 2015;81(3):342–53.
Blanco-Marigota AM, Lozano-Medina A, Marcos JD. The exergetic efficiency as a performance evaluation tool in reverse osmosis desalination plants in operation. Desalination. 2017;413:19–28.
Xu P, Cath TY, Robertson AP, Reinhard M, Leckie JO, Drewes JE. Critical review of desalination concentrate management, treatment and beneficial use. Environ Eng Sci. 2013;30(8):502–14.
Harandi HB, Rahnama M, Javaran EJ, Asadi A. Performance optimization of a multi stage flash desalination unit with thermal vapor compression using genetic algorithm. Appl Therm Eng. 2017;123:1106–19.
Eveloy V, Rodgers P, Qui L. Hybrid gas turbine–organic Rankine cycle for seawater desalination by reverse osmosis in a hydrocarbon production facility. Energy Convers Manag. 2015;106:1134–48.
Jiang SX, Li YN, Ladewig BP. A review of reverse osmosis membrane fouling and control strategies. Sci Total Environ. 2017;595:567–83.
Kämpf J, Clarke B. How robust is the environmental impact assessment process in South Australia? Behind the scenes of the Adelaide seawater desalination project. Mar Policy. 2013;38:500–6.
Garud RM, Kore SV, Kore VS, Kulkarni GS. A short review on process and applications of reverse osmosis. Univers J Environ Res Technol. 2011;1(3):233–8.
Chong TH, Loo S, Fane AG, Krantz WB. Energy-efficient reverse osmosis desalination: effect of retentate recycle and pump and energy recovery device efficiencies. Desalination. 2015;366:15–31.
Wei QJ, McGovern RK, Lienhard VJH. Saving energy with an optimized two-stage reverse osmosis system. Environ Sci Water Resour Technol. 2017;3:659–70.
Aliewi A, El-Sayed E, Akbar A, Hadi K, Al-Rashed M. Evaluation of desalination and other strategic management options using multi-criteria decision analysis in Kuwait. Desalination. 2017;413:40–51.
Chen X, Zhang Z, Liu L, Cheng R, Shi L, Zheng X. RO applications in China: history, current status, and driving forces. Desalination. 2016;39:185–93.
Wu JN, Jin Q, Wang Y, Tandon P. Theoretical analysis and auxiliary experiment of the optimization of energy recovery efficiency of a rotary energy recovery device. Desalination. 2017;415:1–7.
Sim VST, She Q, Chon TH, Tang CY, Fane AG, Krants WB. Strategic co-location in a hybrid process involving desalination and pressure retarded osmosis (PRO). Membranes. 2013;3(3):98–125.
Zhou J, Wang Y, Duan YW, Tian JJ, Xu SC. Capacity flexibility evaluation of a reciprocating-switcher energy recovery device for SWRO desalination system. Desalination. 2017;416:45–53.
Ning L, Zhongliang L, Li Y, Lixia S. Studies on leakage characteristics and efficiency of a fully-rotary valve energy recovery device by CFD simulation. Desalination. 2017;415:40–8.
Heck N, Adina P, Potts D, et al. Predictors of local support for a seawater desalination plant in a small coastal community. Environ Sci Pol. 2016;66:101–11.
Petrik L, Green L, Abegunde AP, Zackon M, Sanusi CY, Barnes J. Desalination and seawater quality at green point, cape town: a study on the effects of marine sewage outfalls. S Afr J Sci. 2017;113(11/12):1–10.
Alshahri F. Heavy metal contamination in sand and sediments near to disposal site of reject brine from desalination plant, Arabian Gulf: assessment of environmental pollution. Environ Sci Pollut Res. 2017;24:1821–34.
Alharbi T, Alfaifi H, Almadani SA, El-Sorogy A. Spatial distribution and metal contamination in the coastal sediments of Al-Khafji area, Arabian Gulf, Saudi Arabia. Environ Monit Assess. 2017;189:634–48.
Naser HA. Assessment and management of heavy metal pollution in the marine environment of the Arabian Gulf: a review. Mar Pollut Bull. 2013;72:6–13.
Jenkins S, Paduan J, Robets P, Schlenk D, Weis J. Management of brine discharges to coastal waters: recommendations of a Science Advisory Panel (Tech. Report No.694). Southern California Coastal Water Research Project. 2012.
Subramani A, Jacangelo JG. Treatment technologies for reverse osmosis concentrate volume minimization: a review. Sep Purif Technol. 2014;122:472–89.
Sanchez AS, Nogueira ABR, Kalid RA. Uses of the reject brine from inland desalination for fish farming, Spirulina cultivation, and irrigation of forage shrub and crops. Desalin. 2015;364:96–107.
Del-Pilar-Ruso Y, Martinez-Garcia E, Gimenews-Casalduero F, Loya-Fernandez A, et al. Benthic community recovery from brine impact after the implementation of mitigation measures. Water Res. 2015;70:325–36.
Ameri M, Eshaghi MS. A novel configuration of reverse osmosis, humidification–dehumidification and flat plate collector: modeling and exergy analysis. Appl Therm Eng. 2016;103:855–73.
Kaner A, Tripler E, Hadas E, Ben-Gal A. Feasibility of desalination as an alternative to irrigation with water high in salts. Desalination. 2017;416:122–8.
Warsinger DM, Tow EW, Nayar KG, Maswadeh LA, Lienhard JH. Energy efficiency of batch and semi-batch (CCRO) reverse osmosis desalination. Water Res. 2016;106(1):272–82.
Zhang S, Chung T. Osmotic power production from seawater brine by hollow fiber membrane modules: net power output and optimum operating conditions. AIChE J. 2016;62(4):1216–25.
Husnil YA, Gregorius RH, Riezqa A, Yus DC, Moonyong L. Conceptual designs of integrated process for simultaneous production of potable water, electricity, and salt. Desalination. 2017;409:96–107.
Lin S, Elimelech M. Kinetics and energetics trade-off in reverse osmosis desalination with different configurations. Desalination. 2012;401:42–52.
Blair D, Alexander DT, Couperthwaite SJ, Darestani M, Millar GJ. Enhanced water recovery in the coal seam gas industry using a dual reverse osmosis system. Environ Sci Water Res Technol. 2017;3:278–92.
Shalaby SM. Reverse osmosis desalination powered by photovoltaic and solar Rankine cycle power systems: a review. Renew Sust Energ Rev. 2017;73:789–97.
Shukla A, Kant K, Sharma A. Solar still with latent heat energy storage: a review. Innovative Food Sci Emerg Technol. 2017;41:34–46.
Sawar J, Mansoor B. Characterization of thermophysical properties of phase change materials for non-membrane based indirect solar desalination application. Energy Convers Manag. 2016;120:247–56.
Author information
Authors and Affiliations
Contributions
N.D. wrote the first draft, and G.S.T. contributed to the revision.
Corresponding author
Ethics declarations
Conflict of Interest
The authors declare that they have no conflict of interest.
Additional information
This article is part of the Topical Collection on Water Pollution
Electronic Supplementary Material
ESM 1
(DOCX 742 kb)
Rights and permissions
About this article
Cite this article
Darre, N.C., Toor, G.S. Desalination of Water: a Review. Curr Pollution Rep 4, 104–111 (2018). https://doi.org/10.1007/s40726-018-0085-9
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40726-018-0085-9