Selective and effective adsorption of cesium ions by metal hexacyanoferrates (MHCF, M = Cu, Co, Ni) modified chitosan fibrous biosorbent

Selective and effective adsorptive removal of radiocesium is of great importance in terms of nuclear waste management and environmental remediation, but is still challenging because of its radioactive and non-complexing nature. Herein, metal hexacyanoferrates (MHCF, M = Cu, Co, or Ni) modified fibrous chitosan was prepared by multiple sequential adsorption and self-assembly approach, and applied for the selective and effective adsorption of Cs+. The physically supported MHCF in chitosan fibers showed good crystallinity and stability, and the obtained fibrous composite has high specific surface area (18.2-29.4 m(2) g(-1)). Moreover, MHCF crystals endowed the fibrous chitosanbased adsorbent with a high adsorption capacity and selectivity towards Cs+. Its adsorption kinetic and isotherm performance followed the pseudo second-order model and the Sips model. The q(m) value of three fibrous MHCF/chitosan (M = Cu, Co, or Ni) composites was 24.9-70.3 mg g(-1). The fibrous CuHCF/chitosan composite had the highest q(m) among the three composites. In summary, the modified chitosan can selectively and effectively remove Cs+ from complicated aqueous solutions.

Automated summary

Selective and effective adsorptive removal of radiocesium is of great importance. In this study, metal hexacyanoferrates modified fibrous chitosan was successfully prepared and applied for the selective and effective adsorption of Cs+. The modified chitosan showed good crystallinity and stability, and had a high specific surface area. The MHCF crystals endowed the chitosan-based adsorbent with a high adsorption capacity and selectivity.