Generation of multi-functional core-shell adsorbents: simultaneous adsorption of cesium, strontium and rhodamine B in aqueous solution

In this study, we design and synthesize multi-functional adsorbents using a customized needle injector and determine the simultaneous adsorption performance toward hazardous materials, including radioac-tive cesium (Cs+), strontium (Sr2+), and chemical dye rhodamine B (Rh B). A tri-functional core is synthe-sized using a tetrapod needle injector, which is equipped with an aligner and a supporter to align the syringe needles, to rapidly realize a one-step encapsulation of functional reagents including Prussian blue, hydroxyapatite, and MXene. Subsequently, a magnetic shell is generated via a chemical co-precipitation process. Results show that the simultaneous adsorption behaviors of the adsorbents toward the three hazardous materials are consistent with the Langmuir model, where maximum adsorption capacities of 42.744, 27.669, and 18.440 mg g(-1) are recorded for Cs+, Sr2+, and Rh B, respectively. In addi-tion, the adsorbents are separated from the aqueous solution within 5 s by the introduction of external magnetic fields, which can be applied to magnetic actuation. We believe that the generated multi-functional adsorbents can facilitate the development of multi-functional materials and provide signifi-cant guidelines for water remediation, particularly on radioactive isotopes and chemical dyes. (C) 2022 The Korean Society of Industrial and Engineering Chemistry. Published by Elsevier B.V. All rights reserved.

Automated summary

In this study, multi-functional adsorbents were designed and synthesized using a customized needle injector. The adsorbents exhibited simultaneous adsorption performance toward radioactive cesium, strontium, and chemical dye rhodamine B, and could be rapidly separated using external magnetic fields.