This paper discusses the promising candidate of excellent materials, graphene oxide (GO) and polyoxometalates (POMs), for radionuclide adsorbent. In this perspective, the unique properties of GO and POMs make them ideal candidates for developing new composites having the ability to adsorb radionuclides, and several essential things are reviewed. First, the anchoring mechanism to deposit POM on the GO surface area by (i) carboxylation method, (ii) covalent bonding, and (iii) impregnation method. Second, the radionuclides removal mechanism is described in several systems: (i) coagulation, (ii) electrostatic interaction, (iii) ion trapping, and (iv) H⁺-exchange. Third, the experimental condition that employed to enlarge the sorption capacity such as (i) pH adjustment, (ii) employing multiple oxidations, and (iii) cation charge. A thorough understanding of the POM-anchored GO material can pave the way for future research on similar materials. It can also help in understanding the nature of the interactive collaboration present between GO and POM.

[1] Yasunari, T.J., Stohl, A., Hayano, R.S., Burkhart, J.F., Eckhardt, S., and Yasunari, T., 2011, Cesium-137 deposition and contamination of Japanese soils due to the Fukushima nuclear accident, Proc. Natl. Acad. Sci. U.S.A., 108 (49), 19530–19534.

[2] Nakanishi, T.M., 2017, Research with radiation and radioisotopes to better understand plant physiology and agricultural consequences of radioactive contamination from the Fukushima Daiichi nuclear accident, J. Radioanal. Nucl. Chem., 311 (2), 947–971.

[3] Tokyo Electric Power Company, 2011, The evaluation status of reactor core damage at Fukushima Daiichi nuclear, power station unit 1 of 3, https://www.tepco.co.jp/en/nu/fukushima-np/images/handouts_111130_04-e.pdf.

[4] Wang, X., Chen, L., Wang, L., Fan, Q., Pan, D., Li, J., Chi, F., Xie, Y., Yu, S., Xiao, C., Luo, F., Wang, J., Wang, X., Chen, C., Wu, W., Shi, W., Wang, S., and Wang, X., 2019, Synthesis of novel nanomaterials and their application in efficient removal of radionuclides, Sci. China Chem., 62 (8), 933–967.

[5] Nishihara, K., Yamagishi, I., Yasuda, K., Ishimori, K., Tanaka, K., Kuno, T., Inada, S., and Gotoh, Y., 2015, Radionuclide release to stagnant water in the Fukushima-1 nuclear power plant 1, J. Nucl. Sci. Technol., 52 (3), 301–307.

[6] Foreman, M.R.S.J., 2015, An introduction to serious nuclear accident chemistry, Cogent Chem., 1 (1), 1049111.

[7] Uchida, S., and Tagami, K., 2007, Soil-to-plant transfer factors of fallout ¹³⁷Cs and native ¹³³Cs in various crops collected in Japan, J. Radioanal. Nucl. Chem., 273 (1), 205–210.

[8] Matsuda, N., and Nakashima, S., 2014, Radioactive cesium in water and soil and its adsorption to rice plant (interim report) (in Japanese), Radiat. Saf. Manage., 13 (1), 84–91.

[9] Nguyen, H.T., Tsujimoto, M., and Nakashima, S., 2019, Study on paddy soil in Fukushima using Mössbauer spectroscopy, Hyperfine Interact., 240 (1), 122.

[10] Koarashi, J., Atarashi-Andoh, M., Matsunaga, T., Sato, T., Nagao, S., and Nagai, H., 2012, Factors affecting vertical distribution of Fukushima accident-derived radiocesium in soil under different land–use conditions, Sci. Total Environ., 431, 392–401.

[11] Tsujimoto, M., Miyashita, S., Nguyen, H.T., and Nakashima, S., 2020, Monthly change in radioactivity concentration of ¹³⁷Cs, ¹³⁴Cs, and ⁴⁰K of paddy soil and rice plants in Fukushima Prefecture, Radiat. Saf. Manage., 19, 10–22.

[12] Basuki, T., Miyashita, S., Tsujimoto, M., and Nakashima, S., 2018, Deposition density of ¹³⁴Cs and ¹³⁷Cs and particle size distribution of soil and sediment profile in Hibara Lake area, Fukushima: An investigation of ¹³⁴Cs and ¹³⁷Cs indirect deposition into lake from surrounding area, J. Radioanal. Nucl. Chem., 316 (3), 1039–1046.

[13] Shizuma, K., Fujikawa, Y., Kurihara, M., and Sakurai, Y., 2018, Identification and temporal decrease of ¹³⁷Cs and ¹³⁴Cs in groundwater in Minami–Soma City following the accident at the Fukushima Dai-ichi nuclear power plant, Environ. Pollut., 234, 1–8.

[14] Steinhauser, G., Brandl, A., and Johnson, T.E., 2014, Comparison of the Chernobyl and Fukushima nuclear accidents: A review of the environmental impacts, Sci. Total Environ., 470-471, 800–817.

[15] Ayabe, Y., Hijii, N., and Takenaka, C., 2017, Effects of local-scale decontamination in a secondary forest contaminated after the Fukushima nuclear power plant accident, Environ. Pollut., 228, 344–353.

[16] Koarashi, J., Atarashi-Andoh, M., Nishimura, S., and Muto, K., 2020, Effectiveness of decontamination by litter removal in Japanese forest ecosystems affected by the Fukushima nuclear accident, Sci. Rep., 10 (1), 6614.

[17] IAEA, 2015, The Fukushima Daiichi Accident: Technical Volume 5–Post-Accident Recovery, International Atomic Energy Agency, Vienna, https://www-pub.iaea.org/MTCD/Publications/PDF/AdditionalVolumes/P1710/Pub1710-TV5-Web.pdf.

[18] del Valle, E.M.M., Galán, M.A., and Carbonell, R.G., 2009, Drug delivery technologies: The way forward in the new decade, Ind. Eng. Chem. Res., 48 (5), 2475–2486.

[19] Tabish, M.S., Hanapi, N.S.M., Ibrahim, W.N.W., Saim, N., and Yahaya, N., 2019, Alginate-graphene oxide biocomposite sorbent for rapid and selective extraction of non-steroidal anti-inflammatory drugs using micro-solid phase extraction, Indones. J. Chem., 19 (3), 684–695.

[20] Nor, N.M., Kamil, N.H.N., Mansor, A.I., and Maarof, H.I., 2020, Adsorption analysis of fluoride removal using graphene oxide/eggshell adsorbent, Indones. J. Chem., 20 (3), 579–586.

[21] Sun, Y., Wang, Q., Chen, C., Tan, X., and Wang, X., 2012, Interaction between Eu(III) and graphene oxide nanosheets investigated by batch and extended x-ray absorption fine structure spectroscopy and by modeling techniques, Environ. Sci. Technol., 46 (11), 6020–6027.

[22] Sun, Y., Shao, D., Chen, C., Yang, S., and Wang, X., 2013, Highly efficient enrichment of radionuclides on graphene oxide-supported polyaniline, Environ. Sci. Technol., 47 (17), 9904–9910.

[23] Ke, Q., and Wang, J., 2016, Graphene-based materials for supercapacitor electrodes – A review, J. Materiomics, 2 (1), 37–54.

[24] Fan, J., Shi, Z., Lian, M., Li, H., and Yin, J., 2013, Mechanically strong graphene oxide/sodium alginate/polyacrylamide nanocomposite hydrogel with improved dye adsorption capacity, J. Mater. Chem. A, 1 (25), 7433–7443.

[25] Debataraja, A., Manurung, R.V., Asri, L.A.T.W., Yuliarto, B., Nugraha, N., and Sunendar, B., 2018, Synthesis and characterization of nanocomposites of tin–oxide graphene doping Pd using Polyol method, Indones. J. Chem., 18 (2), 344–348.

[26] Eigler, S., Dotzer, C., Hof, F., Bauer, W., and Hirsch, A., 2013, Sulfur species in graphene oxide, Chem. Eur. J., 19 (29), 9490–9496.

[27] Petrov, V.G., Chen, Z., Romanchuk, A.Y., Demina, V.O., Tang, Y., and Kalmykov, S.N., 2019, Sorption of Eu(III) onto nano-sized H-titanates of different structures, Appl. Sci., 9 (4), 697.

[28] Tamura, K., Kogure, T., Watanabe, Y., Nagai, C., and Yamada, H., 2014, Uptake of cesium and strontium ions by artificially altered phlogopite, Environ. Sci. Technol., 48 (10), 5808–5815.

[29] Dideikin, A.T., and Vul, A.Y., 2019, Graphene oxide and derivatives: The place in graphene family, Front. Phys., 6, 149.

[30] Szabó, T., Berkesi, O., Forgó, P., Josepovits, K., Sanakis, Y., Petridis, D., and Dékány, I., 2006, Evolution of surface functional groups in a series of progressively oxidized graphite oxides, Chem. Mater., 18 (11), 2740–2749.

[31] Grote, F., Gruber, C., Börrnert, F., Kaiser, U., and Eigler, S., 2017, Thermal disproportionation of oxo-functionalized graphene, Angew. Chem. Int. Ed., 56 (31), 9222–9225.

[32] Hummers, W.S., and Offeman, R.E., 1958, Preparation of graphitic oxide, J. Am. Chem. Soc., 80 (6), 1339.

[33] Ranjan, P., Agrawal, S., Sinha, A., Rao, T.R., Balakrishnan, J., and Thakur, A.D., 2018, A low-cost non-explosive synthesis of graphene oxide for scalable applications, Sci. Rep., 8 (1), 12007.

[34] Cote, L.J., Kim, J., Zhang, Z., Sun, C., and Huang, J., 2010, Tunable assembly of graphene oxide surfactant sheets: Wrinkles, overlaps and impacts on thin film properties, Soft Matter, 6 (24), 6096–6101.

[35] Guerrero-Contreras, J., and Caballero-Briones, F., 2015, Graphene oxide powders with different oxidation degree, prepared by synthesis variations of the Hummers method, Mater. Chem. Phys., 153, 209–220.

[36] Xu, Y., Liu, Z.W., Xu, Y.L., Zhang, Y.Y., and Wu, J.L., 2014, Preparation and characterization of graphene/ZnS nanocomposites via a surfactant-free method, J. Exp. Nanosci., 9 (4), 415–420.

[37] Romanchuk, A.Y., Slesarev, A.S., Kalmykov, S.N., Kosynkin, D.V., and Tour, J.M., 2013, Graphene oxide for effective radionuclide removal, Phys. Chem. Chem. Phys., 15 (7), 2321–2327.

[38] Seliman, A.F., Lasheen, Y.F., Youssief, M.A.E., Abo-Aly, M.M., and Shehata, F.A., 2014, Removal of some radionuclides from contaminated solution using natural clay: Bentonite, J. Radioanal. Nucl. Chem., 300 (3), 969–979.

[39] Mahmoud, M.R., Sharaf El-deen, G.E., and Soliman, M.A., 2014, Surfactant-impregnated activated carbon for enhanced adsorptive removal of Ce(IV) radionuclides from aqueous solutions, Ann. Nucl. Energy, 72, 134–144.

[40] Kaewmee, P., Manyam, J., Opaprakasit, P., Le, G.T.T., Chanlek, N., and Sreearunothai, P., 2017, Effective removal of cesium by pristine graphene oxide: Performance, characterizations and mechanisms, RSC Adv., 7 (61), 38747–38756.

[41] Semcuk, S., 2018, Application of graphene oxide based nanocomposites and Šaltiškiai clay for radionuclides removal from contaminated solutions, Dissertation, Institute of Physics of the State Research Institute for Physical Science and Technology, Vilnius University, Lithuania.

[42] Yang, H., Sun, L., Zhai, J., Li, H., Zhao, Y., and Yu, H., 2014, In situ controllable synthesis of magnetic Prussian blue/graphene oxide nanocomposites for removal of radioactive cesium in water, J. Mater. Chem. A, 2 (2), 326–332.

[43] Bubeníková, M., Ecorchard, P., Szatmáry, L., Mrózek, O., Salačová, P., and Tolasz, J., 2018, Sorption of Sr(II) onto nanocomposites of graphene oxide-polymeric matrix, J. Radioanal. Nucl. Chem., 315 (2), 263–272.

[44] Morimoto, N., Kubo, T., and Nishina, Y., 2016, Tailoring the oxygen content of graphite and reduced graphene oxide for specific applications, Sci. Rep., 6 (1), 21715.

[45] Ebajo, V.D., Santos, C.R.L., Alea, G.V., Lin, Y.A., and Chen, C.H., 2019, Regenerable acidity of graphene oxide in promoting multicomponent organic synthesis, Sci. Rep., 9 (1), 15579.

[46] Nováček, M., Jankovský, O., Luxa, J., Sedmidubský, D., Pumera, M., Fila, V., Lhotka, M., Klímová, K., Matějková, S., and Sofer, Z., 2017, Tuning of graphene oxide composition by multiple oxidations for carbon dioxide storage and capture of toxic metals, J. Mater. Chem. A, 5 (6), 2739–2748.

[47] Xia, T., Qi, Y., Liu, J., Qi, Z., Chen, W., and Wiesner, M.R., 2017, Cation-inhibited transport of graphene oxide nanomaterials in saturated porous media: The Hofmeister effects, Environ. Sci. Technol., 51 (2), 828–837.

[48] Pope, M.T., and Müller, A., 1991, Polyoxometalate chemistry: An old field with new dimensions in several disciplines, Angew. Chem. Int. Ed. Engl., 30 (1), 34–48.

[49] Nyman, M., and Burns, P.C., 2012, A comprehensive comparison of transition- metal and actinyl polyoxometalates, Chem. Soc. Rev., 41 (22), 7354–7367.

[50] Wihadi, M.N.K., Hayashi, A., Ichihashi, K., Ota, H., Nishihara, S., Inoue, K., Tsunoji, N., Sano, T., and Sadakane, M., 2019, A sandwich complex of bismuth cation and mono-lacunary α-Keggin-type phosphotungstate: preparation and structural characterization, Eur. J. Inorg. Chem., 2019 (3-4), 357–362.

[51] Hatcher, J.L., 2018, Fundamental chemistry related to separations and coordination of actinium-225, thorium-227, and technetium-99, Dissertation, The Graduate Center, City University of New York, US.

[52] Petit, C., and Bandosz, T.J., 2009, Graphite oxide/polyoxometalate nanocomposites as adsorbents of ammonia, J. Phys. Chem. C, 113 (9), 3800–3809.

[53] Seino, S., Kawahara, R., Ogasawara, Y., Mizuno, N., and Uchida, S., 2016, Reduction-induced highly selective uptake of cesium ions by an ionic crystal based on silicododecamolybdate, Angew. Chem. Int. Ed., 55 (12), 3987–3991.

[54] Kim, K.C., Pope, M.T., Gama, G.J., and Dickman, M.H., 1999, Slow proton exchange in aqueous solution. Consequences of protonation and hydration within the central cavity of Preyssler anion derivatives, [|M(H₂O)|⊃P₅W₃₀O₁₁₀]^n–, J. Am. Chem. Soc., 121 (48), 11164–11170.

[55] Li, H., Pang, S., Feng, X., Müllen, K., and Bubeck, C., 2010, Polyoxometalate assisted photoreduction of graphene oxide and its nanocomposite formation, Chem. Commun., 46 (34), 6243–6245.

[56] Wang, R., Dang, L., Liu, Y., and Jiao, W., 2019, Preparation, characterization and photocatalytic activity of Dawson type phosphotungstate/graphene oxide composites, Adv. Powder Technol., 30 (7), 1400–1408.

[57] Liu, Y., Liu, S., Lai, X., Miao, J., He, D., Li, N., Luo, F., Shi, Z., and Liu, S., 2015, Polyoxometalate-modified sponge-like graphene oxide monolith with high proton-conducting performance, Adv. Funct. Mater., 25 (28), 4480–4485.

[58] Kim, Y., and Shanmugam, S., 2013, Polyoxometalate-reduced graphene oxide hybrid catalyst: Synthesis, structure, and electrochemical properties, ACS Appl. Mater. Interfaces, 5 (22), 12197–12204.

[59] Herrmann, S., De Matteis, L., de la Fuente, J.M., Mitchell, S.G., and Streb, C., 2017, Removal of multiple contaminants from water by polyoxometalate supported ionic liquid phases (POM-SILPs), Angew. Chem. Int. Ed., 56 (6), 1667–1670.

[60] Liu, Y., Luo, F., Liu, S., Liu, S., Lai, X., Li, X., Lu, Y., Li, Y., Hu, C., Shi, Z., and Zheng, Z., 2017, Aminated graphene oxide impregnated with photocatalytic polyoxometalate for efficient adsorption of dye pollutants and its facile and complete photoregeneration, Small, 13 (4), 1603174.

[61] Sures, D.J., and Nyman, M., 2017, “Anomalous cesium ion behavior in aqueous polyoxometalate solutions” in Cesium: Properties, Production and Application, Eds. Hall, B., Nova Science Publisher, Inc., New York, 119–148.

[62] Hitose, S., and Uchida, S., 2018, Rapid uptake/release of Cs⁺ in isostructural redox-active porous ionic crystals with large-molecular-size and easily reducible Dawson-type polyoxometalates as building blocks, Inorg. Chem., 57 (9), 4833–4836.

[63] Belloni, F., Kütahyali, C., Rondinella, V.V., Carbol, P., Wiss, T., and Mangione, A., 2009, Can carbon nanotubes play a role in the field of nuclear waste management?, Environ. Sci. Technol., 43 (5), 1250–1255.

[64] Ammam, M., 2013, Polyoxometalates: Formation, structures, principal properties, main deposition, methods and application in sensing, J. Mater. Chem. A, 1 (21), 6291–6312.

[65] Miras, H.N., Yan, J., Long, D.L., and Cronin, L., 2012, Engineering polyoxometalates with emergent properties, Chem. Soc. Rev., 41 (22), 7403–7430.

[66] Kawahara, R., Uchida, S., and Mizuno, N., 2015, Redox-induced reversible uptake-release of cations in porous ionic crystals based on polyoxometalate: Cooperative migration of electrons with alkali metal ions, Chem. Mater., 27 (6), 2092–2099.