[1] N R SOELBERG, T G GARN, M R GREENHALGH et al. Radioactive iodine and krypton control for nuclear fuel reprocessing. facilities. Science and Technology of Nuclear Installations, 702496(2013).
[2] M A SABRI, M H AL-SAYAH, S SEN et al. Fluorescent aminal linked porous organic polymer for reversible iodine capture and sensing. Scientific Reports, 15943(2020).
[3] V UYBA, A SAMOYLOV, S SHINKAREV. Comparative analysis of the countermeasures taken to mitigate exposure of the public to radioiodine following the Chernobyl and Fukushima accidents: lessons from both accidents. Journal of Radiation Research, ii40-ii47(2018).
[4] G SUNAVALA-DOSSABHOY. Radioactive iodine: an unappreciated threat to salivary gland function. Oral Diseases, 198-201(2018).
[5] Y FENG, G WEI, Y LIU et al. Crystallization behavior of boron in low-temperature immobilization of iodine waste. Journal of Solid State Chemistry, 122698(2022).
[6] B J RILEY, J D VIENNA, D M STRACHAN et al. Materials and processes for the effective capture and immobilization of radioiodine: a review. Journal of Nuclear Materials, 470, 307-326(2016).
[7] I BEGHI, T LIND, H M PRASSER. Experimental studies on retention of iodine in a wet scrubber. Nuclear Engineering and Design, 326, 234-243(2018).
[8] J HUVE, A RYZHIKOV, H NOUALI et al. Porous sorbents for the capture of radioactive iodine compounds: a review. RSC Advances, 29248-29273(2018).
[9] J ZHOU, S HAO, L GAO et al. Study on adsorption performance of coal based activated carbon to radioactive iodine and stable iodine. Annals of Nuclear Energy, 72, 237-241(2014).
[10] M ALSALBOKH, N FAKERI, S LAWSON et al. Adsorption of iodine from aqueous solutions by aminosilane-grafted mesoporous alumina. Chemical Engineering Journal, 128968(2021).
[11] S CHONG, B J RILEY, W KUANG et al. Iodine capture with mechanically robust heat-treated Ag-Al-Si-O xerogel sorbents. ACS Omega, 11628-11638(2021).
[12] G LIN, L ZHU, T DUAN et al. Efficient capture of iodine by a polysulfide-inserted inorganic NiTi-layered double hydroxides. Chemical Engineering Journal, 122181(2019).
[13] X PAN, C DING, Z ZHANG et al. Functional porous organic polymer with high S and N for reversible iodine capture. Microporous and Mesoporous Materials, 110161(2020).
[14] T ASSAAD, B ASSFOUR. Metal organic framework MIL-101 for radioiodine capture and storage. Journal of Nuclear Materials, 493, 6-11(2017).
[15] Y TANG, H HUANG, J LI et al. IL-induced formation of dynamic complex iodide anions in IL@MOF composites for efficient iodine capture. Journal of Materials Chemistry A, 18324-18329(2019).
[16] D AKIYAMAA, T ISHIIA, Y MASAKIA et al. Sorption and desorption of radioactive organic iodine by silver doped zeolite and zeolite X.. Journal of Nuclear and Radiochemical Sciences, 21, 1-6(2021).
[17] A T REDA, D ZHANG, X XU et al. Bismuth-impregnated aluminum/copper oxide-pillared montmorillonite for efficient vapor iodine sorption. Separation and Purification Technology, 118848(2021).
[18] A T REDA, M PAN, D ZHANG et al. Bismuth-based materials for iodine capture and storage: a review. Journal of Environmental Chemical Engineering, 105279(2021).
[19] G E GU, J BAE, H S PARK et al. Development of the functionalized nanocomposite materials for adsorption/decontamination of radioactive pollutants. Materials, 2896(2021).
[20] K PHILIPPOU, C N CHRISTOU, V SOCOLIUC et al. Superparamagnetic polyvinylpyrrolidone/chitosan/Fe3O4 electrospun nanofibers as effective U(VI) adsorbents. Journal of Applied Polymer Science, 50212(2021).
[21] S LIU, S KANG, H WANG et al. Nanosheets-built flowerlike micro/nanostructured Bi2O2.33 and its highly efficient iodine removal performances. Chemical Engineering Journal, 289, 219-230(2016).
[22] J H YANG, J M SHIN, J J PARK et al. Novel synthesis of bismuth-based adsorbents for the removal of 129I in off-gas. Journal of Nuclear Materials, 457, 1-8(2015).
[23] G DAS, T SKORJANC, S K SHARMA et al. Viologen-based conjugated covalent organic networks via Zincke reaction. Journal of the American Chemical Society, 9558-9565(2017).
[24] Y WANG, G A SOTZING, R WEISS. Sorption of iodine by polyurethane and melamine-formaldehyde foams using iodine sublimation and iodine solutions. Polymer, 2728-2740(2006).
[25] Q ZHAO, L ZHU, G LIN et al. Controllable synthesis of porous Cu-BTC@polymer composite beads for iodine capture. ACS Applied Materials & Interfaces, 42635-42645(2019).
[26] A MILLER, Y WANG. Al-O-F materials as novel adsorbents for gaseous radioiodine capture. Journal of Environmental Radioactivity, 133, 35-39(2014).
[27] Y NAN, L L TAVLARIDES, D W DEPAOLI. Adsorption of iodine on hydrogen-reduced silver-exchanged mordenite: experiments and modeling. AIChE Journal, 1024-1035(2017).
[28] L WU, J A SAWADA, D B KUZNICKI et al. Iodine adsorption on silver-exchanged titania-derived adsorbents. Journal of Radioanalytical and Nuclear Chemistry, 527-532(2014).
[29] A P KATSOULIDIS, J HE, M G KANATZIDIS. Functional monolithic polymeric organic framework aerogel as reducing and hosting media for Ag nanoparticles and application in capturing of iodine vapors. Chemistry of Materials, 1937-1943(2012).
[30] S CHONG, B J RILEY, J A PETERSON et al. Gaseous iodine sorbents: a comparison between Ag-loaded aerogel and xerogel scaffolds. ACS Applied Materials & Interfaces, 26127-26136(2020).
[31] H ZOU, F YI, M SONG et al. Novel synthesis of Bi-Bi2O3-TiO2-C composite for capturing iodine-129 in off-gas. Journal of Hazardous Materials, 365, 81-87(2019).
[32] G LI, Y HUANG, J LIN et al. Effective capture and reversible storage of iodine using foam-like adsorbents consisting of porous boron nitride microfibers. Chemical Engineering Journal, 122833(2020).