Bondar Yu., Kuzenko S., Slyvinsky V.

Abstract

The development of selective adsorbents for liquid radioactive waste amount reduction is an actual problem. Composite adsorbents with the active ferrocyanide phase are of particular interest for ¹³⁷Cs removal from contaminated waters. Polymer fibers are a promising host solid support for the synthesis of composite adsorbents because composite fibers can be synthesized through a one-stage experiment by formation of ferrocyanide layer on the fibers’ surface in a solution (in situ).Composite adsorbent based on polyacrylonitrile fibers was synthesized by in situ formation of the ferricyanide K-Cu layer on the fibers’ surface. This paper presents the experimental data on ¹³⁷Cs removal from model solutions prepared from distilled water and high-saline solution from Liman Kuyalnik brine.It was found that the synthesized composite fibers with ferrocyanide K-Cu layer can effectively remove ¹³⁷Сs from both solutions. In the case of solution based on distilled water, the adsorption efficiency was 93% and the distribution coefficient – 4,1х10³ cm³/g. High selectivity with regard to ¹³⁷Сs is confirmed by the data on adsorption from the high-saline solution prepared from Liman Kuyalnik brine.  In the case of a high concentration of competing sodium and potassium ions in the solution, the adsorption efficiency and distribution coefficient were 99% and 1,9х10⁴ cm³/g, respectively.The obtained results are similar to those for the composite polyacrylonitrile fibers with the ferricyanide K-Ni layer, while the composite fibers with the ferricyanide K-Cu layer demonstrate higher adsorption parameters. The synthesized composite fibers can be recommended for the removal of cesium radionuclides from natural and industrial waters, as well as for the decontamination of low-level liquid radioactive waste with a high content of competing potassium and sodium ions.

Key words: composite adsorbent, polyacrylonitrile fibers, potassium-copper ferrocyanide, selectivity, ¹³⁷Cs, liquid radioactive waste.

 

Article

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