11/28/2023 0 Comments Caesium ion![]() Appl Chem Ind 46(7):1377–1382īayülken S, Başçetin E, Güçlü K, Apak R (2011) Investigation and modeling of cesium(I) adsorption by Turkish clays: bentonite, zeolite, sepiolite, and kaolinite. Sep Purif Technol 38(2):149–161īao AM, Qian ZQ, Zheng H, Liu ZY, Huang DF, Wang SY, Liu B (2017) Progress of separation and extraction methods for rare alkali metals rubidium and cesium. J Radioanal Nucl Chem 261(3):551–557īalarama Krishna MV, Rao SV, Arunachalam J, Murali MS, Kumar S, Manchanda VK (2004b) Removal of 137Cs and 90Sr from actual low level radioactive waste solutions using moss as a phyto-sorbent. J Magn Magn Mater 184(2):241–244īalarama Krishna MV, Arunachalam J, Murali MS, Kumar S, Manchanda VK (2004a) Performance of immobilized moss in the removal of 137Cs and 90Sr from actual low-level radioactive waste solutions. J Radioanal Nucl Chem 260(2):321–326īahaj AS, Croudace IW, James PAB, Moeschler FD, Warwick PE (1998) Continuous radionuclide recovery from wastewater using magnetotactic bacterial. J Hazard Mater 195:73–81īaeza A, Fernandez M, Herranz M, Legarda F, Miro C, Salas A (2004) Elimination of man-made radionuclides from natural waters by applying a standard coagulation–flocculation process. Desalination 154(1):27–33Īttallah MF, Borai EH, Hilal MA, Shehata FA, Abo-Aly MM (2011) Utilization of different crown ethers impregnated polymeric resin for treatment of low level liquid radioactive waste by column chromatography. Desalination 154:35–42Īrnal JM, Sancho M, Verdú G, Campayo JM, Villaescusa JI (2003b) Treatment of 137Cs liquid wastes by reverse osmosis Part I. J Radioanal Nucl Chem 298(1):537–545Īrnal JM, Sancho M, Verdú G, Campayo JM, Gozálvez JM (2003a) Treatment of 137Cs liquid wastes by reverse osmosis Part II. J Hazard Mater 344:511–530Īrarem A, Bouras O, Bouzidi A (2013) Batch and continuous fixed-bed column adsorption of Cs + and Sr 2+ onto montmorillonite-iron oxide composite: comparative and competitive study. Chem Soc Rev 41(10):3859–3877Īlby D, Charnay C, Heran M, Prelot B, Zajac J (2017) Recent developments in nanostructured inorganic materials for sorption of cesium and strontium: synthesis and shaping, sorption capacity, mechanisms, and selectivity-a review. Chem Soc Rev 45(1):203–224Īlbelda MT, Frias JC, Garcia-Espana E, Schneider HJ (2012) Supramolecular complexation for environmental control. Chem Commun 52(35):5940–5942Īguila D, Prado Y, Koumousi ES, Mathoniere C, Clerac R (2016b) Switchable Fe/Co Prussian blue networks and molecular analogues. Arab J Nucl Sci Appl 49(4):177–188Īguila B, Banerjee D, Nie Z, Shin Y, Ma S, Thallapally PK (2016a) Selective removal of cesium and strontium using porous frameworks from high level nuclear waste. Adsorption-based methods are high efficient in separation of cesium ions from aqueous streams, and adsorption of cesium ions has been investigated intensively and even used in practical applications, there is still considerable scope for improvement in terms of adsorption capacity and selectivity.Ību-Khadra SA, Killa HM, Abdelmalik WEY, Elrafie M (2016) A study of some parameters affecting the biosorption of 137Cs radionuclide by non-living biomass. Particular attention has been paid to the adsorption methods, which has been highlighted by introducing the latest advances in inorganic adsorbents (such as metal hexacyanoferrates, clay minerals, carbon-based-adsorbents, and ammonium molybdophosphate), organic adsorbents (such as ion exchange resin, metal–organic frameworks and supramolecular/indicator grafting adsorbents), and biosorbents (such as agroforestry wastes and microbial biomass). The key restraints for cesium removal, as well as the recent progress of these methods have also been discussed. This review focused on cesium removal using various separation technologies, including chemical precipitation, solvent extraction, membrane separation, and adsorption. ![]() However, the development of innovative technologies capable of selectively removing radioactive cesium is still imperative yet challenging. Different methods such as chemical precipitation, coagulation/co-precipitation, solvent extraction, membrane process, chemical reduction, and adsorption have been used to remove radioactive cesium from aqueous solution. Radiocesium has potential adverse effects on human health and ecological environment.
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