Preparation, characterization and ion-exchange behavior of polyantimonic acid-polyacrylonitrile (PAA–PAN) composite beads for strontium(II)

Effective radioactive strontium removal using lithium titanate decorated Ti3C2Tx MXene/polyacrylonitrile beads

A lithium titanate-decorated Ti3C2Tx MXene (LTO-MX) composite was synthesized through etching and alkali processes, and subsequently immobilized using polyacrylonitrile (PAN) polymer via a phase inversion method. In the batch study, the strontium adsorption behavior followed the Redlich-Peterson isotherm and the pseudo-second-order kinetic models. The maximum adsorption capacity for strontium reached 24.05 mg/g. Furthermore, a continuous fixed-bed column study was performed using the LTO-MX PAN beads to remove strontium from aqueous solutions. The dynamic behavior of column adsorption was examined under various operating parameters such as initial strontium concentration, flow rate, and bed height. Dynamic modeling was employed to describe adsorption breakthrough properties based on these experimental data. Both the Thomas and Yoon-Nelson models accurately simulated the breakthrough curves. The proposed mechanisms for strontium adsorption included encapsulation, electrostatic attraction, cation exchange, and surface complexation. These results demonstrate the effectiveness of LTO-MX PAN beads as adsorbents for the continuous removal of strontium from radioactive wastewater.

Development of polystyrene coated persulfate slow-release beads for the oxidation of targeted PAHs: Effects of sulfate and chloride ions

In this study, we synthesized polystyrene coated persulfate polyacrylonitrile beads (PC-PSPANBs) to control persulfate (PS) release for targeted PAHs' degradation in a batch reactor. Initially, the persulfate release rate (k_sr = 20.553 h^-1) from PSPANBs was fast, but coating the PSPANBs with polystyrene controlled PS release rate (k_sr= 2.841 h^-1), nearly ten times slower than without coating. When Fe(II) activated PC-PSPANBs applied for 12 h degradation of acenaphthene (ACE), 2-methlynaphthalene (2-MN) and dibenzofuran (DBF), the optimum percent removal efficiencies (% R.Es) were as ACE (82.12%) > DBF (68.57%) > 2-MN (58.80%) and the optimum degradation rate constants (k_obs) were found as ACE (11.348 h^-1) > 2-MN (3.441 h^-1) > DBF (1.101 h^-1). The effect of SO₄^2- and Cl^- on ACE degradation showed that % R.E and k_obs were enhanced with increasing anionic concentrations. The maximum % R.E was achieved for SO₄^2- (76.24%) > Cl^- (65.51%), but the highest k_obs was in case of Cl^- (1.536 h^-1) > SO₄^2- (0.510 h^-1). The effectiveness of PS release longevity was also found because net degradations of ACE and DBF after first spiking were 12 mg L^-1 and 16 mg L^-1, while after second spiking were 18 mg L^-1 and 10 mg L^-1, respectively.

Millimeter-sized Bi2S3@polyacrylonitrile hybrid beads for highly efficient iodine capture

Chemisorption of iodine by forming BiI₃was the main capturing mechanism of Bi₂S₃@PAN for iodine.