UraniumDecontamination fromWaste Soils byChlorinationwith ZrCl4 in LiCl-KCl Eutectic Salt

'e dissolution behavior of U, contained in the soils, was examined through chlorination with ZrCl4 to reduce the U concentration to clearance levels. Natural soils, composed of Si, Al, and approximately 2 ppm U, acted as surrogates for the contaminated soils. A salt mixture of LiCl-KCl-ZrCl4 was prepared in an Al2O3 crucible at 500°C, and SiO2 or natural soils were loaded for the chemical reactions. 'e reaction of SiO2 and Al2O3 with ZrCl4 was monitored by cyclic voltammetry, and no obvious change was observed.'e results showed that SiO2 and Al2O3 were stable against ZrCl4. 'e reaction of natural soils with ZrCl4 indicated that the U content decreased from 2 to 1.2 ppm, while ∼0.4 ppm U appeared in the salt. 'us, the U, in the soils, dissolved into the salt by chlorination with ZrCl4. 'erefore, based on these results, a new method to remediate U-contaminated soil wastes by chlorination with ZrCl4, followed by electrorefining of U, is suggested.


Introduction
Technologies that contribute to the effective decommissioning and/or dismantling of nuclear power plants are essential, especially considering that many power plants are close to the end of their design life. e dismantling of nuclear facilities produces a significant amount of radioactive waste; one such major waste is radiation-contaminated soil [1]. It is thus necessary to develop suitable technology for decontaminating the soil for disposal. Simultaneous improvement in the volume reduction of waste will significantly reduce the disposal costs and result in the efficient utilization of depository space [2].
Two research reactors and a U conversion facility have been decommissioned in Korea, generating a significant amount of radioactive soil, which is currently in temporary storage. Figure 1 shows the categories for the radioactive wastes established by Korea Institute of Nuclear Safety [3]. e majority of these soils show very low-level radioactivity, i.e., 60 Bq/g (the clearance level for U is 1 Bq/g, and thus, very low-level wastes are those that show radioactivity below 100 Bq/g). However, this number is still 60-fold greater than the permissible radioactivity for clearance. Despite the extremely low levels of radioactivity, these soils are considered as radioactive waste and therefore cannot be disposed normally.
us, decontamination of the soils, to a level below that of deregulation, is essential.
In the aforementioned stored soils, the main contaminating radionuclide is U, and thus, the radioactivity must be reduced below 1 Bq/g for deregulation and safe disposal [3]. Contaminated soils are generally remediated by washing techniques, such as wet screening, and chemical treatments with various organic and inorganic acids, bases, salts, and chelating agents [1,4]. However, these chemical treatments produce secondary waste, thereby reducing the decontamination efficiency. us, a technique that can remediate the soils, without generating secondary radioactive waste, must be developed.
e key technique for the reduction of secondary radioactive wastes is the selective dissolution of uranium oxide, which is the main contaminant. Herein, we introduce the selective dissolution of U via a chlorination of UO 2 with ZrCl 4 in LiCl-KCl molten salt (equation (1); UO 2 is assumed a crystal structure of U): (1) In this study, we examined the dissolution behavior of U, contained in soils, through chlorination with ZrCl 4 . Natural soils were used as surrogates for the contaminated soils showing extremely low-level radioactivity. e reactivity of SiO 2 and Al 2 O 3 (which are the major components in soils) with ZrCl 4 was evaluated to estimate the dissolution behavior of the main soil products. e change in the concentration of U in the natural soils was examined, before and after the chlorination with ZrCl 4 . A salt mixture-LiCl-KCl-ZrCl 4 -was prepared in an Al 2 O 3 crucible at 500°C, and SiO 2 or natural soils were immersed in it to induce a chlorination, which was monitored via cyclic voltammetry (CV). e natural soils were characterized, before and after the chemical reaction, to evaluate the amount of UO 2 dissolved. Based on these experimental results, herein, a possible method for the remediation of radiation-contaminated soils is suggested.

Materials and Methods
LiCl-KCl eutectic salt (Alfa Aesar, A Johnson Matthey Company, purity > 99.9%) was dried at 500°C, under vacuum, before use. ZrCl 4 (Alfa Aesar, A Johnson Matthey Company, purity > 99.5%) was dissolved into the molten LiCl-KCl for the preparation of LiCl-KCl-ZrCl 4 . SiO 2 (Sigma-Aldrich, purity > 99.5%, ∼325 mesh) and natural soils were used for the chlorination. e natural soils, used as the surrogate material for U-contaminated soils, were collected near the dismantled nuclear facility. e soils were sieved by 70 mesh, indicating that the particle sizes were less than 210 μm.
160 g of LiCl-KCl were loaded into an Al 2 O 3 crucible (diameter: 70 mm and height: 55 mm), which was then heated to 500°C. 9.2 g of ZrCl 4 was added into the molten LiCl-KCl, and temperature was maintained for 4.3 h. 50 g of SiO 2 was added into LiCl-KCl-ZrCl 4 , in the Al 2 O 3 crucible, at 500°C, and the temperature was maintained for 4 h. e consumption of ZrCl 4 was monitored from the peak intensity for oxidation/reduction of Zr 4+ via CV (Bio-Logic, SP-300 potentiostat/galvanostat) during the chlorination of SiO 2 and Al 2 O 3 with ZrCl 4 . e cell configuration is shown in Figure 2. A W wire (diameter: 1 mm, Nilaco Corp., Japan) and glassy carbon (diameter: 3 mm, Alfa Aesar, USA) were immersed into the salt to be used as a working electrode and counter electrode, respectively. An Ag wire inserted into LiCl-KCl-1 mol% AgCl loaded in a Pyrex tube was used as a reference electrode. e distance between working and counter electrode was 25 mm. e CV was measured at a potential from 0 to −1.6 V in a scan rate of 100 mV/s. A detailed description of measurement was already described in a previous report [5].
e LiCl-KCl-ZrCl 4 mixture was heated to 500°C, and 50 g of natural soils were placed in the crucible for the chlorination of natural soils with ZrCl 4 . e temperature of the mixture was maintained for over 20 h, and then it was gradually cooled to room temperature. e soils were then water washed to remove the adhered salt and mix homogeneously. And then the soils were vacuum dried for characterization. e crystal structures of the samples were studied by X-ray diffraction (XRD), using a multipurpose attachment X-ray diffractometer (Bruker Corp. D8 ADVANCE, USA) with an X-ray tube producing Cu Kα radiation. e morphology and chemical composition were observed via scanning electron microscopy (SEM) (Hitachi Ltd. S-8010, Japan), in conjunction with energy dispersive X-ray spectroscopy (EDS) (Horiba Ltd. EX-250 X-max, Japan). e soil compositions, before and after the reaction, were analyzed by inductively coupled plasma mass spectrometry (ICP-MS) ( ermo Fisher Scientific, iCAP Qc). e uncertainty in the ICP measurements was within the range, 1-10%, depending on the element. e change in the Gibbs free energy, with the reaction of various oxides and ZrCl 4 , was calculated by using the HSC Chemistry v.9 (Outotec Oyj, Finland) software [6], as a function of temperature from 0°C to 700°C.

Results
To estimate the reaction trend of soils against ZrCl 4 , we characterized the composition of natural soils collected near the dismantled nuclear facility. Figure 3 shows the crystal structure of the soils. A pattern for illite, which consists of Si, Al, K, and OH, is mainly observed. OH was attributed to the adhered water on the soils because the samples were analyzed without drying. A pattern for SiO 2 is also provided here.
e chemical composition, observed by SEM-EDS, confirmed that the main components of the soils were Si and Al, as shown in Table 1. Fe was present in minor concentrations.
Considering the composition of soils, thermodynamic reactivity of various oxides containing Si, Al, Fe, and U was estimated against ZrCl 4 . Figure 4 shows the changes in the Gibbs free energy for the reactions as a function of the temperature, calculated using HSC Chemistry v. 9. e major components, SiO 2 and Al 2 O 3 , were estimated to be stable against ZrCl 4 , showing positive values for the changes in the free energy at temperatures below 600°C. However, the changes in the free energy became smaller with increasing temperature, showing negative values for SiO 2 at temperatures above 600°C. Furthermore, UO 2 was estimated to react with ZrCl 4 , showing negative free energy changes. In this study, we assumed that the crystal structure of uranium oxide was UO 2 , as we could not define the crystal structure due to its small contents. e results suggest that UO 2 can be   as described in Section 4. e chlorination of SiO 2 with ZrCl 4 was carried out in an Al 2 O 3 crucible to confirm the stability of SiO 2 and Al 2 O 3 because the thermodynamic estimation showed that the free energy changes became smaller as the temperature increased ( Figure 4). SiO 2 was immersed into LiCl-KCl-5.4 wt% ZrCl 4 , which was loaded in the Al 2 O 3 crucible at 500°C and maintained for 4 h. e reaction was monitored by the intensity decrease of Zr 4+ peak in CV measurement. Figure 5 shows the CV pattern of the salt mixture, before and after the reaction test, showing oxidation/reduction peaks of Zr 4+ at −0.9 and −1.2 V [9]. No obvious change was observed. e result confirms that SiO 2 and Al 2 O 3 were stable against ZrCl 4 at the reaction temperature. e reaction test of natural soils and ZrCl 4 was performed to examine the dissolution behavior of U. Natural soils were used as surrogates for the radioactive soil waste. As mentioned before, the primary aim of this study was to develop an effective soil-remediation method to reduce the radioactivity of radiation-contaminated soils to a level below the clearance level ( Figure 1); therefore, the U in the natural soils was suitable as a surrogate in an extreme case. e concentration of U in the natural soils was characterized by ICP-MS, and it was found that approximately 2.0 ppm of U was contained in the natural soils. 50 g of natural soils were immersed into LiCl-KCl-5.4 wt% ZrCl 4 at 500°C and maintained for 20 h for sufficient reaction with ZrCl 4 . Figure 6 shows the soils before and after the reaction. e soils settled to the bottom of the crucible after the reaction (Figure 6

Discussion
e results of the reaction between soils and ZrCl 4 in LiCl-KCl salt showed that the U, in radioactive soils, selectively dissolved into the salt mixture, leaving behind the major soil components-SiO 2 and Al 2 O 3 -unaffected. In addition, the very lowlevel (below the clearance level) U, in natural soils, was successfully dissolved into the LiCl-KCl salts during the chlorination of the natural soils with the salt mixture, suggesting that the U in the contaminated soils can be removed for deregulation by utilizing the method described, in this paper. e U, dissolved in the LiCl-KCl salts, seems to behave similarly to that, in the pyroprocess, i.e., the U in salt can be recovered almost completely by electrolysis. e U recovery, utilizing the electrorefining technique, is one of the most important processes in pyroprocessing, which recycles the U and transuranic materials for fuel fabrication [10,11]. It is confirmed that almost all of the U can be recovered, from the LiCl-KCl-UCl 3 mixture, by this process [12][13][14].
erefore, herein, we suggest a new method to remediate the U-contaminated radioactive waste via chlorination with ZrCl 4 , followed by electrorefining of U. Figure 7 shows a schematic of the process. First, the U-contaminated soils are immersed in the LiCl-KCl-ZrCl 4 salt at 500°C for reaction with ZrCl 4 (equation (1)), to selectively dissolve the U into the salt mixture. Second, the U in the salt is recovered by electrorefining on the cathode. e selective recovery of only U from the soils can dramatically reduce the volume of the radioactive waste.   Science and Technology of Nuclear Installations 5 As shown in Table 1, ∼4.4 wt% of Fe was contained in the soils, as a minor component, and possibly dissolved into the salt due to a reaction between Fe 2 O 3 and ZrCl 4 , as implied by the negative free energy changes ( Figure 4). erefore, Fe, dissolved into the LiCl-KCl salt, can be separated by Fe electrorefining, without U contamination, which is evident from the significant difference of equilibrium potential between Fe and U (the equilibrium potentials of Fe and U are approximately −0.7 V and −1.5 V, respectively [7,8]). Moreover, the U possibly deposited on the cathode would dissolve again into the salt by the chlorination of U with FeCl 3 (equation (2) (2) Even though K and Ca can dissolve from the soils into the salts (Table 1), they are quite small and stable and do not affect the electrorefining; KCl is one of the main components of the electrolytes; the standard potential of Ca, depositing on the cathode, is considerably low. us, the proposed method, which consists of a chlorination of the contaminated soils with ZrCl 4 in LiCl-KCl salt followed by electrorefining, can remediate the U-contaminated soils, generating negligible secondary radioactive waste.

Conclusions
e dissolution behavior of U, contained in natural soils, with ZrCl 4 in LiCl-KCl salt was examined. e concentration of U in the soils was evaluated before and after the test. e following results were obtained: (i) SiO 2 and Al 2 O 3 were estimated to be stable for the chlorination with ZrCl 4 , while UO 2 was destabilized, as indicated by the thermodynamic calculations (ii) e chlorination test of SiO 2 and Al 2 O 3 , which were the main component of soils, confirmed their stability against ZrCl 4 in LiCl-KCl (iii) e U in the natural soils was successfully dissolved into LiCl-KCl by chlorination with ZrCl 4 , even though the initial U was extremely small Based on these results of the laboratory test that 40% of U was dissolved from natural soils into LiCl-KCl salt by the chlorination with ZrCl 4 , we suggest a new method to remediate the U-contaminated soils by chlorination and followed by U electrorefining. We believe that the U dissolved into the LiCl-KCl salt can be recovered by U electrorefining similarly to the pyroprocess. Further research studies of a bench scale are planned to figure out the feasibility of the proposed method.

Data Availability
e data used to support the findings of this study are included within the article. Disclosure e preliminary study on the chemical reaction of ZrCl 4 and soils was presented as a poster in 16th International Symposium on Novel and Nano Materials (ISNNM) (2020), Phoenix Jeju, Korea, PMP-P19.  6 Science and Technology of Nuclear Installations