References

1. R. Bertani, Geothermal Power Generation in the World 2010–2014 Update Report, In: Proceedings World Geothermal Congress 2015, 19–25 April 2015, Melbourne, Australia.
2. L. Pajak, W. Bujakowski, Geothermal energy in binary systems, Geol. Rev., 11/2 (2013) 699–705.
3. J.W. Lund, T.L. Boyd, Direct Utilization of Geothermal Energy 2015: Worldwide Review, In: Proceedings World Geothermal Congress 2015, 19–25 April 2015, Melbourne, Australia.
4. J. Bundschuh, G. Chen, B. Tomaszewska, N. Ghaffour, S. Mushtaq, I. Hamawand, K. Reardon-Smith, T. Maraseni, T. Banhazi, H. Mahmoudi, M. Goosen, L.D. Antille, Solar, Wind and Geothermal Energy Applications in Agriculture: Back to the Future? J. Bundschuh, G. Chen, D. Chandrasekharam, J. Piechocki, Eds., Geothermal, Wind and Solar Energy Applications in Agriculture and Aquaculture, CRC Press; Taylor & Francis Group, cop., London, 2017 (Sustainable Energy Developments; ISSN 2164-0645), ISBN: 978-1-138-02970-5; e-ISBN: 978-1-315-15896-9, pp. 1–32.
5. A. Baba, Application of geothermal energy and its environmental problems in Turkey, Int. J. Global Environ. Issues, 14 (2015) 321–331.
6. B. Tomaszewska, M. Bodzek, Desalination of geothermal waters using a hybrid UF-RO process. Part I. Boron removal in pilotscale tests, Desalination, 319 (2013) 99–106.
7. B. Tomaszewska, Geothermal Water Treatment in Poland, J. Bundschuh, B. Tomaszewska, Eds., Geothermal Water Management, CRC Press, Taylor & Francis Group, cop., London, 2018, Sustainable Water Developments: Resources, Management, Treatment, Efficiency and Reuse; ISSN 2373-7506; vol. 6. ISBN: 978-1-138-02721-3; e-ISBN: 978-1-315-73497-2, pp. 255–278.
8. B. Tomaszewska, L. Pająk, J. Bundschuh, W. Bujakowski, Low-enthalpy geothermal energy as a source of energy and integrated freshwater production in inland areas: technological and economic feasibility, Desalination, 435 (2018) 35–44.
9. N. Voutchkov, Overview of seawater concentrate disposal alternatives, Desalination, 273 (2011) 205–219.
10. A. Péréz-González, A.M. Urtiaga, R. Ibánez, I. Ortiz, State of the art and review on the treatment technologies of water reverse osmosis concentrates, Water Res., 46 (2012) 267–283.
11. R. Ibáñez, A. Pérez-Gonzalez, J. Pinedo, P. Gomez, A.M. Urtiaga, I. Ortiz, Review of Direct Discharge and Recovery of RO Concentrates, J. Bundschuh, B. Tomaszewska, Eds., Geothermal Water Management, CRC Press, Taylor & Francis Group, cop., London, 2018, Sustainable Water Developments: Resources, Management, Treatment, Efficiency and Reuse; ISSN 2373-7506; vol. 6. ISBN: 978-1-138-02721-3; e-ISBN: 978-1-315-73497-2, pp. 233–254.
12. B. Tomaszewska, L. Pająk, M. Bodzek, Application of a hybrid UF-RO process to geothermal water desalination. Concentrate disposal and costs analysis, Archit. Environ. Prot., 40 (2014) 137–151.
13. A. Subramani, J.G. Jacangelo, Treatment technologies for reverse osmosis concentrate volume minimization: a review, Sep. Purif. Technol., 122 (2014) 472–489.
14. P. Chelme-Ayala, D.W. Smith, M.G. El-Din, Membrane concentrate management options: a comprehensive critical review, Can. J. Civ. Eng., 36 (2009) 1107–1119.
15. PZH, 2017 – Ocena właściwości biochemicznych koncentratów pozyskanych w wyniku uzdatniania wód geotermalnych w aspekcie możliwości ich wykorzystania do celów kosmetycznych lub profilaktycznych [“Assessment of biochemical properties of concentrates obtained as a result of the treatment of geothermal waters with respect to the possibility of using them for cosmetic or prophylactic purposes”]. Zakład Tworzyw Uzdrowiskowych [Department of Materials Used in Spa Treatments] in Poznań of Państwowy Zakład Higieny [National Institute of Hygiene] in Warsaw (unpublished).
16. NIZP, 2015 – Radiological tests of the water from Mszczonów IG-1. Narodowy Instytut Zdrowia Publicznego – Państwowy Zakład Higieny (National Institute of Public Health – National Institute of Hygiene) in Warsaw (unpublished).
17. WHO, World Health organisation, Guidelines for Drinking- Water Quality, 4th ed., 2011, ISBN: 978 92 4 154815 1.
18. G. Hua, D.A. Reckhow, J. Kim, Effect of bromide and iodide ions on the formation and speciation of disinfection byproducts during chlorination, Environ. Sci. Technol., 40 (2006) 3050–3056.
19. G. Micale, A. Cipollina, A. Tamburini, Salinity Gradient Energy, A. Cipollina, G. Micale, Eds., Sustainable Energy from Salinity Gradient, Elsevier Ltd., Woodhead Publisher Series in Energy: No. 95, Kidlington, 2016, ISBN: 978-0-08-100312-1.
20. R.E. Pattle, Brit. Pat. Application, 1939/63 (Jan. 22, 1953), 1953.
21. R. Kempener, F. Neumann, Salinity Gradient Energy, Technology Brief, 2014, Available from: www.irena.org, accessed April 2018.
22. D.A. Vermaas, E. Guler, M. Saakes, K. Nijmeijer, Theoretical power density from salinity gradient using reverse electrodialysis, Energy Procedia, 20 (2012) 170–184.
23. E. Guler, Anion Exchange Membrane Design for Reverse Electrodialysis, PhD Dissertation, University of Twente, Enschede, January 2014.
24. D. Brogioli, Extracting renewable energy from a salinity difference using a capacitor, Phys. Rev. Lett., 103 (2009) 058501.
25. D. Brogioli, R. Ziano, R.A. Rica, D. Salerno, F. Mantegazza, Capacitive mixing for the extraction of energy from salinity differences: survey of experimental results and electrochemical models, J. Colloid Interface Sci., 407 (2013) 457–466.
26. M. Fernandez, R. Wagterveld, S. Ahualli, F. Liu, A. Delgado, H. Hamelers, Polyelectrolyte- vs. membrane-coated electrodes for energy production by capmix salinity exchange methods, J. Power Sources, 302 (2016) 387–393.
27. G. Iglesias, S. Ahualli, M. Fernandez, M. Jimenez, A. Delgado, Stacking of capacitive cells for electrical energy production by salinity exchange, J. Power Sources, 318 (2016) 283–290.
28. Z. Jia, B. Wang, S. Song, Y. Fan, Blue energy: current technologies for sustainable power generation from water salinity gradient, Renewable Sustainable Energy Rev., 31 (2014) 91–100.