Preparation of the Nanostructured Radioisotope Metallic Oxide by Neutron Irradiation for Use as Radiotracers

: Metallic oxides manganese dioxide (MnO 2 ), samarium oxide (Sm 2 O 3 ), and dysprosium oxide (Dy 2 O 3 ) with nanorod-like structures were synthesized by the hydrothermal synthesis method, respectively. Subsequently, the nanostructured radioisotopes MnO 2 with Mn-56, Sm 2 O 3 with Sm-153, and Dy 2 O 3 with Dy-165 were prepared by neutron irradiation from the HANARO research reactor, respectively. The three different elements, Mn, Sm, and Dy, were selected as radiotracers because these elements can be easily gamma-activated from neutrons (activation limits: 1 picogram (Dy), 1–10 picogram (Mn), 10–100 picogram (Sm)). Furthermore, the synthesized radioisotopes can be used as radiotracers in Prompt Gamma Neutron Activation Analysis as the rare earth metals Dy and Sm were not present in the Korean environment. The successful synthesis of the radioisotope metallic oxides was conﬁrmed by Transmission Electron Microscopy (TEM), Energy Dispersive X-ray Spectrometry (EDS), X-ray Diffraction (XRD) analysis, and gamma spectroscopy analysis. The synthesized nanostructured radioisotope metallic oxides may be used as radiotracers in scientiﬁc, environmental, engineering, and industrial ﬁelds.


Introduction
Nanostructured metallic oxides can be prepared by various methods, such as a combination of the template-based method and sol-gel chemistry [1][2][3][4], the facile wet chemical method [5], and the hydrothermal method [6][7][8][9]. Hydrothermal synthesis has been an interesting technique for preparing materials with different nano-architectures, such as nanowires, nanorods, nanobelts, and nanoflowers [10][11][12], and its main advantage over other soft chemical routes is the ability to control the nanostructures by choosing the proper reaction temperature, time, solvent, and concentration without the need for any major structure-directing agents or templates. The effects of temperature, time, solvent, and concentration on the morphologies of powders prepared by the hydrothermal method have been extensively studied and reported [13,14]; however, to our knowledge, there have been few studies on hydrothermal synthesis of rare earth metal oxides for use as radiotracers.
Rare earth metallic oxide radiotracers can be used widely in science and engineering, particularly for industrial use, because they have high activation limits and rare metal elements, although they should be physically and chemically compatible with the material under investigation. A radiotracer for injection is labeled radioactively with a given material that allows it to be monitored as it moves through a system by external radiation detectors [15,16]. Radiotracers must be produced relatively easily and cheaply by nuclear reactors and accelerators. Their chemical form is also important because they need to be in the same phase as the process medium, either aqueous or organic, and remain in that intended medium throughout the monitoring process.
Radioisotope nanoparticles (NPs) have been synthesized with core-198 Au shell-silica ( 198 Au@SiO 2 ) by neutron irradiation from the HANARO nuclear research reactor at the Korea Atomic Energy Research Institute (Daejeon, Korea) [17]. These core-shell radioisotope NPs have good physical and mechanical property because of SiO 2 shells in high energy gamma environments; however, the preparation process of 198 Au@SiO 2 radioisotope NPs is very complicated because of the capsulation of 197 Au NPs using SiO 2 in the presence of anchoring agents. Furthermore, only a very small amount of 198 Au@SiO 2 radioisotope NPs could be obtained because the Au NPs used as starting materials are commonly synthesized in amounts under 10 −3 M (mol/L). In addition, core-shell radioisotope NPs with multi gamma-emitting nuclides have been prepared by neutron irradiation at the HANARO research reactor [18]. The synthesis method of the core-shell radioisotope NPs with gamma-emitting nuclides have low yields. Therefore, synthesis methods with easy, simple, and good yields are needed to prepare radioisotope NPs for their use as radiotracers in various scientific, engineering, and industrial fields.
In this study, nanostructured metallic oxides of MnO 2 , Sm 2 O 3 , and Dy 2 O 3 were synthesized by the hydrothermal process under various reaction conditions. The metallic oxides obtained were characterized by Transmission Electron Microscopy (TEM), Energy Dispersive X-ray Spectrometry (EDXS), Scanning Electron Microscopy (SEM), and X-ray Diffraction (XRD) analysis. Next, after calcination of the as-synthesized metallic oxides, radioisotope metallic oxides were synthesized by neutron irradiation from the HANARO research reactor. Finally, successful synthesis of the nanostructured metallic oxide radioisotopes was confirmed via gamma spectroscopy analysis.

Synthesis of Radioisotopes MnO 2 , Sm 2 O 3 , and Dy 2 O 3 NPs by Neutron Irradiation
Manganese dioxide (MnO 2 ) was synthesized by redox hydrothermal synthesis in aqueous solution at 120 • C for 8 h, as given by the following equation: In detail, 1.93 g (8.00 mmol) manganese sulfate monohydrate (MnSO 4 ·H 2 O) and 2.61 g (8.0 mmol) ammonium persulfate ((NH 4 ) 2 S 2 O 8 ) were put into 50 mL distilled water at room temperature to form a homogeneous solution, which was then transferred into a 100-mL Teflon-lined stainless-steel autoclave. The sealed solution was kept at 120 • C for 8 h. After the autoclave was cooled down to room temperature naturally, the obtained products were filtered and washed with distilled water to remove any remaining ions. The as-prepared materials were dried overnight in a vacuum oven at 80 • C. In order to remove the organic elements, the as-prepared MnO 2 samples were calcined at 900 • C for 2 h under an air atmosphere. Finally, the nanostructured radioisotope MnO 2 was synthesized by neutron irradiation using the HANARO research reactor (Korea Atomic Energy Research Institute).
Samarium oxide (Sm 2 O 3 ) NPs can be synthesized by the W/O (water/oil) emulsion process and the calcination process as in the following equations: In the first step, 2.0 mL of 1.5 mol/L Sm(NO 3 ) 3 aqueous solution was added to 1.0 g pentanol as a cosurfactant, 8.0 g n-octane as an organic solvent, and the appropriate amount of surfactant cetyltrimethylammonium bromide (CTAB), and then the mixture was agitated until it became a transparent microemulsion. The temperature was maintained by putting the whole setup into a thermostatic water bath. The microemulsion was slowly added to an NaOH aqueous solution under agitation, and this finally led to the formation of a suspension of surfactant-stabilized SmOH. After being stirred for 1 h, the suspension was allowed to stand for 24 h at a specified temperature to obtain as large an amount as possible of surfactant-stabilized SmOH NPs (in the form of a precipitate). The precipitate was then collected by centrifuging and washed several times with pure ethanol and distilled water. The collected products were dried in a vacuum oven at 75 • C for 5 h. In the second step, the dried precipitate (SmOH) was calcined at 500 • C for 6 h in the oxygen state to obtain the primrose yellow Sm 2 O 3 nanoparticles. Finally, nanostructured radioisotope Sm 2 O 3 was synthesized by neutron irradiation (neutron flux: 4.2 × 10 13 n·cm −2 ·s −1 ) of the as-prepared Sm 2 O 3 powder by the HANARO research reactor (Korea Atomic Energy Research Institute).
Dysprosium oxide (Dy 2 O 3 ) powder can be synthesized by the redox process and the calcination process as in the following equations: In detail, 5 mmol of Dy(NO 3 ) 3 ·H 2 O was added to 40 mL of triethylene glycol in a 100-mL three-necked flask, and the solution was stirred magnetically until the precursor was completely dissolved into the solvent. In a separate flask, 15 mmol of NaOH was dissolved in 10 mL of methanol and the resulting solution was added dropwise to the precursor solution. The reaction mixture was heated to 200 • C and refluxed for 24 h with magnetic stirring. Then, the dried precipitate (the precursor) was calcined at 500 • C for 6 h in an air atmosphere to obtain Dy 2 O 3 NPs. Finally, radioisotope Dy 2 O 3 NPs were synthesized by neutron irradiation (neutron flux: 4.2 × 10 13 n·cm −2 ·s −1 ) of the as-prepared Dy 2 O 3 NPs by the HANARO research reactor (Korea Atomic Energy Research Institute).

Characteristics of Radioisotope Metallic Oxide NPs
The morphologies of the as-prepared metallic oxide samples were analyzed by High Resolution Transmission Electron Microscopy (HR-TEM) (JEM-2010F, JEOL Ltd., Tokyo, Japan). An energy dispersive X-ray spectrometer (EDXS) attached to the HR-TEM was used to analyze their chemical compositions. An X-ray Diffractometer (XRD) (D8 ADVANCE, Bruker AXS, Karlsruhe, Germany) was applied to determine the nanostructures. To ensure the chemical purity of the NPs, their gamma spectrum was measured with an HPGe (high purity germanium) detector (EG&G Ortec, 25% relative efficiency, FWHM 1.85 keV at 1332 keV of 60 Co) coupled to a 16K-multichannel analyzer.

Results and Discussion
The successful synthesis of MnO 2 NPs by the hydrothermal process is shown by the TEM image and EDS (Energy Dispersive Spectrometry) data of the nanostructured MnO 2 powder (Figure 1). It can be seen from the TEM images that the nanostructured MnO 2 powder exhibits rod-like structures that consist of nanofibers with a diameter of 50 nm. Form the EDS data, the atomic percentage (%) of Mn element and O element was 31.3% and 62.5%, respectively (Figure 1c). After neutron irradiation, the morphology of the MnO 2 was not changed. This result means that the nanostructured MnO 2 showed high stability under neutron irradiation.  A neutron activation analysis of the prepared nanoparticles was carried out at the HANARO research reactor (neutron flux: 4.2 × 10 13 n•cm −2 •s −1 ), a nuclear research reactor at the Atomic Energy Research Institute. A 3.7-mg sample was activated for 20 s, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma energies of Mn-56 ( Figure 3). The results showed that the radioisotope was successfully synthesized by neutron irradiation after hydrothermal synthesis of the nanostructured MnO2 NPs. In order to obtain nanostructured Sm2O3 powder, first nanostructured SmOH was synthesized by the W/O emulsion process. Then, to obtain pure Sm2O3 powder, the SmOH powder was calcinated at 900 °C for 2 h under an air atmosphere. The Sm2O3 powder was successfully synthesized by the microemulsion process and the calcination process, as shown by the TEM image and EDS data of the Sm2O3 powder after calcinations ( Figure 4). All of the Sm2O3 nanopowder had a rod shape with the dimensions of 36 × 185 nm. As shown by the EDS data, the percentage (%) of Sm element and O element was 31.3% and 62.5%, respectively. After the neutron irradiation, the morphology of the Sm2O3 powder was changed from a rod-like structure to an amorphous structure. A neutron activation analysis of the prepared nanoparticles was carried out at the HANARO research reactor (neutron flux: 4.2 × 10 13 n·cm −2 ·s −1 ), a nuclear research reactor at the Atomic Energy Research Institute. A 3.7-mg sample was activated for 20 s, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma energies of Mn-56 ( Figure 3). The results showed that the radioisotope was successfully synthesized by neutron irradiation after hydrothermal synthesis of the nanostructured MnO 2 NPs. A neutron activation analysis of the prepared nanoparticles was carried out at the HANARO research reactor (neutron flux: 4.2 × 10 13 n•cm −2 •s −1 ), a nuclear research reactor at the Atomic Energy Research Institute. A 3.7-mg sample was activated for 20 s, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma energies of Mn-56 ( Figure 3). The results showed that the radioisotope was successfully synthesized by neutron irradiation after hydrothermal synthesis of the nanostructured MnO2 NPs. In order to obtain nanostructured Sm2O3 powder, first nanostructured SmOH was synthesized by the W/O emulsion process. Then, to obtain pure Sm2O3 powder, the SmOH powder was calcinated at 900 °C for 2 h under an air atmosphere. The Sm2O3 powder was successfully synthesized by the microemulsion process and the calcination process, as shown by the TEM image and EDS data of the Sm2O3 powder after calcinations (Figure 4). All of the Sm2O3 nanopowder had a rod shape with the dimensions of 36 × 185 nm. As shown by the EDS data, the percentage (%) of Sm element and O element was 31.3% and 62.5%, respectively. After the neutron irradiation, the morphology of the Sm2O3 powder was changed from a rod-like structure to an amorphous structure. In order to obtain nanostructured Sm 2 O 3 powder, first nanostructured SmOH was synthesized by the W/O emulsion process. Then, to obtain pure Sm 2 O 3 powder, the SmOH powder was calcinated at 900 • C for 2 h under an air atmosphere. The Sm 2 O 3 powder was successfully synthesized by the microemulsion process and the calcination process, as shown by the TEM image and EDS data of the Sm 2 O 3 powder after calcinations (Figure 4). All of the Sm 2 O 3 nanopowder had a rod shape with the dimensions of 36 × 185 nm. As shown by the EDS data, the percentage (%) of Sm element and O element was 31.3% and 62.5%, respectively. After the neutron irradiation, the morphology of the Sm 2 O 3 powder was changed from a rod-like structure to an amorphous structure. XRD data of the Sm 2 O 3 powder after the calcination process ( Figure 5) showed that the diffraction peaks of the Sm 2 O 3 powder were very weak, indicating an amorphous structure. All the peaks assigned by the diffraction of crystalline Sm 2 O 3 at 2Θ = 19.9, 28.3, 32.8, 47.0, and 55.7 • correspond to the (211), (222), (400), (440), and (622) planes (JCPDS card 43-1029). Evident broad peaks were a mixture of the amorphous and nanocrystalline nature of the samples.
Appl. Sci. 2017, 7, 1115 6 of 10 XRD data of the Sm2O3 powder after the calcination process ( Figure 5) showed that the diffraction peaks of the Sm2O3 powder were very weak, indicating an amorphous structure. All the peaks assigned by the diffraction of crystalline Sm2O3 at 2Θ = 19.9, 28.3, 32.8, 47.0, and 55.7° correspond to the (211), (222), (400), (440), and (622) planes (JCPDS card 43-1029). Evident broad peaks were a mixture of the amorphous and nanocrystalline nature of the samples.  For gamma spectroscopy analysis, a 5.42 mg sample of the as-prepared Sm2O3 powder was activated for 10 s by neutron irradiation, and the gamma spectrum was then measured after cooling XRD data of the Sm2O3 powder after the calcination process ( Figure 5) showed that the diffraction peaks of the Sm2O3 powder were very weak, indicating an amorphous structure. All the peaks assigned by the diffraction of crystalline Sm2O3 at 2Θ = 19.9, 28.3, 32.8, 47.0, and 55.7° correspond to the (211), (222), (400), (440), and (622) planes (JCPDS card 43-1029). Evident broad peaks were a mixture of the amorphous and nanocrystalline nature of the samples.  For gamma spectroscopy analysis, a 5.42 mg sample of the as-prepared Sm2O3 powder was activated for 10 s by neutron irradiation, and the gamma spectrum was then measured after cooling For gamma spectroscopy analysis, a 5.42 mg sample of the as-prepared Sm 2 O 3 powder was activated for 10 s by neutron irradiation, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma peaks at 103 keV and 69.7 keV of Sm-153 ( Figure 6). These results showed that the radioisotope Sm 2 O 3 NPs were successfully synthesized by the neutron irradiation of the as-prepared Sm 2 O 3 NPs that were synthesized by the microemulsion process and the calcination process.
for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma peaks at 103 keV and 69.7 keV of Sm-153 ( Figure 6). These results showed that the radioisotope Sm2O3 NPs were successfully synthesized by the neutron irradiation of the as-prepared Sm2O3 NPs that were synthesized by the microemulsion process and the calcination process. The successful synthesis of the Dy2O3 powder with nanorod structures obtained by the redox process and the calcination process is shown by the results of the TEM image and EDS data ( Figure  7). The morphology of Dy2O3 powder exhibited nanorod-like structures with dimensions of 3 × 15 nm in the TEM image. As EDS data shows, the percentage (%) of the Dy element and O element was 28.9% and 71.1%, respectively. After neutron irradiation, the morphology was not changed. From this result, the prepared Dy2O3 was shown to have high stability under neutron irradiation.    For gamma spectroscopy analysis, a 1.74-mg sample of the as-prepared Dy2O3 powder was activated for 10 s by neutron irradiation, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma peaks at 94.7 keV, 361.7 keV, 633.4 keV, and 715.3 keV of Dy-165 ( Figure 9). These results showed that the radioisotope Dy2O3 nanorods were successfully synthesized by the neutron irradiation of the asprepared Dy2O3 nanorods that were synthesized by the redox process and the calcination process. For gamma spectroscopy analysis, a 1.74-mg sample of the as-prepared Dy 2 O 3 powder was activated for 10 s by neutron irradiation, and the gamma spectrum was then measured after cooling for 10 min. The peaks in the gamma spectrum were assigned to the characteristic gamma peaks at 94.7 keV, 361.7 keV, 633.4 keV, and 715.3 keV of Dy-165 ( Figure 9). These results showed that the radioisotope Dy 2 O 3 nanorods were successfully synthesized by the neutron irradiation of the as-prepared Dy 2 O 3 nanorods that were synthesized by the redox process and the calcination process. We expect that the radioisotope Dy 2 O 3 nanorods can be used as radiotracers in scientific, environmental, engineering, and industrial fields. We expect that the radioisotope Dy2O3 nanorods can be used as radiotracers in scientific, environmental, engineering, and industrial fields.

Conclusions
Radioisotopes MnO2, Sm2O3, and Dy2O3 with nanorod-like structures were successfully synthesized by neutron irradiation from the HANARO research reactor after hydrothermal synthesis of MnO2, Sm2O3, and Dy2O3, respectively. The radioisotope MnO2 with a nanorod-like structure showed gamma emission from radioactive Mn-56 with 847 keV, 1811 keV, 2113 keV, 2522 keV, 2567 keV, and 2959 keV. The radioisotope Sm2O3 showed gamma emission from radioactive Sm-153 with

Conclusions
Radioisotopes MnO 2 , Sm 2 O 3 , and Dy 2 O 3 with nanorod-like structures were successfully synthesized by neutron irradiation from the HANARO research reactor after hydrothermal synthesis of MnO 2 , Sm 2 O 3 , and Dy 2 O 3 , respectively. The radioisotope MnO 2 with a nanorod-like structure showed gamma emission from radioactive Mn-56 with 847 keV, 1811 keV, 2113 keV, 2522 keV, 2567 keV, and 2959 keV. The radioisotope Sm 2 O 3 showed gamma emission from radioactive Sm-153 with 69.7 keV and 103 keV. The radioisotope Dy 2 O 3 exhibited gamma emission from radioactive Dy-165 with 94.7 keV, 361.7 keV, 633.3 keV, and 715.3 keV. These synthesized nanostructured radioisotope metallic oxides can be used as radiotracers.