References
- Hammond, C.R. The elements. https://www-d0.fnal.gov/hardware/cal/lvps_info/engineering/elements.pdf
- Petrová, Š.; Soudek, P.; Vaněk, T., Remediace oblastí těžby uranu v České republice. Chemické Listy 2013, 107(4), 283–291.
- Pitter, P. Hydrochemie, 4 edn.; UCT Prague: Prague, Czech Republic, 2009.
- SZÚ. Stanovisko Státního zdravotního ústavu – Národního referenčního centra pro pitnou vodu k limitní hodnotě uranu v pitné vodě; SZÚ: Prague, Czech Republic, 2013.
- Patočka, J.; Kassa, J.; Štětina, R.; Šafr, G.; Havel, J. Toxicological aspects of depleted uranium. J. Appl. Biomed. 2004, 2, 37–42.
- Jeligová, H. Uran v pitné vodě – aktuální toxikologické informace. In Konzultační den Hygieny životního prostředí, SZÚ: Prague, Czech Republic, 2009. http://www.szu.cz/uploads/documents/chzp/ovzdusi/konz_dny_a_seminare/konz_den_hzp_2009/07_kozisek_uran_zdr_rizika.pdf
- WHO. Uranium in Drinking-Water; WHO: Geneva, Switzerland; 2012. http://www.who.int/water_sanitation_health/publications/2012/background_uranium.pdf
- Hritcu, D.; Humelnicu, D.; Dodi, G.; Popa, M. I., Magnetic chitosan composite particles: evaluation of thorium and uranyl ion adsorption from aqueous solutions. Carbohydrate Polymers 2012, 87(2), 1185–1191.
- Donat, R.; Aytas, S. Adsorption and thermodynamic behavior of uranium(VI) on Ulva sp.-Na bentonite composite adsorbent. J. Radioanal. Nucl. Chem. 2005, 265(1), 107–114.
- Bai, J.; Wu, X.; Fan, F.; Tian, W.; Yin, X.; Zhao, L.; Fan, F.; Li, Z.; Tian, L.; Qin, Z.; Guo, J., Biosorption of uranium by magnetically modified Rhodotorula glutinis. Enzyme and Microb. Technol. 2012, 51(6–7), 382–387.
- Li, Z.; Chen, F.; Yuan, L.; Liu, Y.; Zhao, Y.; Chai, Z.; Shi, W., Uranium(VI) adsorption on graphene oxide nanosheets from aqueous solutions. Chem. Eng. J. 2012, 210, 539–546.
- Fasfous, I.I.; Dawoud, J.N. Uranium (VI) sorption by multiwalled carbon nanotubes from aqueous solution. Appl. Surf. Sci. 2012, 259, 433–440.
- Riegel, M.; Tokmachev, M.; Hoell, W.H. Kinetics of uranium sorption onto weakly basic anion exchangers. React. Funct. Polym. 2008, 68(6), 1072–1080.
- Rychkov, V.N.; Smirnov, A.L.; Gortsunova, K.R. Sorption of uranium from underground leaching solutions with highly basic anion exchangers. Radiochemistry 2014, 56(1), 38–42.
- Zagorodnyaya, A.N.; Abisheva, Z.S.; Sadykanova, S.E.; Sharipova, A.S. Sorption of rhenium and uranium from solutions of their joint presence by weakly basic anion exchanger A170. Tsvetnye Metally 2014, 5, 53–60.
- Astheimer, L.; Schenk, H.J.; Witte, E.G.; Schwochau, K. Development of sorbers for the recovery of uranium from seawater. Part 2. The accumulation of uranium from seawater by resins containing amidoxime and imidoxime functional groups. Sep. Sci. Technol. 1983, 18(4), 307–339.
- Hirotsu, T. Studies on Adsorption of Uranium onto Amidoxime Polymers in Sea Water. diploma thesis, Government Industrial Research Institute, Shikoku, 2-3-3 Hananomiya-cho, Takamatsu, Takamatsu, 1987.
- Nilchi, A.; Babalou, A.A.; Rafiee, R.; Sid Kalal, H. Adsorption properties of amidoxime resins for separation of metal ions from aqueous systems. React. Funct. Polym. 2008, 68(12), 1665–1670.
- Vernon, F.; Shah, T. The extraction of uranium from seawater by poly(amidoxime)/poly(hydroxamic acid) resins and fibre. React. Polym. Ion Exch. Sorbents 1983, 1(4), 301–308.
- Zhang, A.; Uchiyama, G.; Asakura, T. Dynamic-state adsorption and elution behaviour of uranium(VI) ions from seawater by a fibrous and porous adsorbent containing amidoxime chelating functional groups. Adsorpt. Sci. Technol. 2003, 21(8), 761–773.
- Zhang, A.; Uchiyama, G.; Asakura, T. The adsorption properties and kinetics of uranium(VI) with a novel fibrous and polymeric adsorbent containing amidoxime chelating functional group from seawater. Sep. Sci. Technol. 2003, 38(8), 1829–1849.
- Gönder, B.Z.; Kaya, Y.; Vergili, I.; Barlas, H. Capacity loss in an organically fouled anion exchanger. Desalination 2006, 189(1), 303–307.
- Cope, A.C.; Mehta, A.S. Mechanism of the hofmann elimination reaction: an ylide intermediate in the pyrolysis of a highly branched quaternary hydroxide. J. Am. Chem. Soc. 1963, 85(13), 1949–1952.
- Cheng, J.; He, G.; Zhang, F. A mini-review on anion exchange membranes for fuel cell applications: Stability issue and addressing strategies. Int. J. Hydrogen Energy 2015, 40(23), 7348–7360.
- Flowers, R.C.; Singer, P.C. Anion exchange resins as a source of nitrosamines and nitrosamine precursors. Environ. Sci. Technol. 2013, 47(13), 7365–7372.
- Moskvin, L.N.; Rakov, V.T.; Yakimova, N.M. Effect of the degradation of ion-exchange resins on the quality of high-purity water prepared by ion-exchange deionization. Russ. J. Appl. Chem. 2016, 89(6), 926–929.
- Ergun, S. Fluid flow through packed columns. J. Chem. Eng. Prog. 1952, 48(2), 89–94.
- Product data sheet Lewatit® DW 630. Lanxess 2011. http://www.lenntech.com/Data-sheets/Lewatit-DW-630-L.pdf
- Product data sheet AmberliteTM IRA910 Cl. Rohm and Haas. http://www.lenntech.com/Data-sheets/Amberlite-IRA-910-Cl-L.pdf
- Product data sheet AmberjetTM 4200 Cl. Rohm and Haas; 2007. http://www.dow.com/assets/attachments/business/ier/ier_for_industrial_water_treatment/amberjet_4200_cl/tds/amberjet_4200_cl.pdf
- Zaganiaris, E.J. Ion Exchange Resins in Uranium Hydromettalurgy; Books on Demand GmbH: Paris, France; 2009.