Highly stable iodine capture by pillared montmorillonite functionalized Bi2O3@g-C3N4 nanosheets

[Display omitted] •Bi2O3@g-CNN functionalized Bi-PILC produces Bi2O3@g-CNN-PILC composite material.•The capture capacity of Bi2O3@g–CNN–PILC for I2 (g) is 830 ± 44 mg/g.•Bi2O3@g-CNN-PILC capture I2 via BiOI, BiI3, N∙∙∙I, and I2@pore formation mechanisms.•Only 18.7% weight of Bi2O3@g-CNN-PILC-I lost when heated up to 800 °C. Nuclear power is the potential to satisfy the global electricity demand. Iodine (I2) is an essential input for the fission fuel but also key output as radioactive waste. Thus, efficient capture and long-term storage of iodine is a high priority. Herein, a novel composite of Bi2O3 doped graphitic carbon nitride nanosheets and bismuth-pillared interlayered clay, abbreviated as Bi2O3@g–CNN–PILC, for vapor iodine capture is reported. The Bi2O3 doped graphitic carbon nitride nanosheets (Bi2O3@g-CNN) is served to capture the iodine and the bismuth-pillared interlayered clay (Bi-PILC) to provide high stability. The capture capacity of Bi2O3@g–CNN–PILC for vapor iodine is 830 ± 44 mg/g at 100 °C within an equilibrium time of almost eight hours despite low specific surface area (SBET = 11.4566 m2/g). Chemical and physical iodine capture mechanisms were involved. Accordingly, direct reaction of I2 with Bi2O3/Bi to produce BiI3 and BiOI and charge transfer from the nitrogen lone pair sites were identified as chemisorption processes. The other proposed sorption mechanism (physisorption) was the pore filling (I2@pore) process. Thermogravimetric analysis showed that the Bi2O3@g-CNN-PILC material has lost only 10.7% and 18.7% of its weight before and after iodine capture, respectively, when heated up to 800 °C, showing how stable the material is. According to these preliminary results, the authors highly recommend this material for further investigation as it could be potential iodine storage in the nuclear industry.