TY - JOUR
T1 - Sorption Behavior of Radionuclides on Engineered and Natural Barriers and Prediction of Sorption Distribution Coefficients Using Support Vector Regression
AU - Lim, Youngsu
AU - Oh, Gi Taek
AU - Kim, Bolam
AU - Kim, Jinseob
AU - Park, Juhui
AU - Lee, Seongju
AU - Choi, Seho
AU - Jang, Jiseon
AU - Kang, Myunggoo
AU - Ha, Jaechul
AU - Cho, Chun Hyung
AU - Lee, Min Woo
AU - Lee, Dae Sung
N1 - Publisher Copyright:
© 2023 Youngsu Lim et al.
PY - 2023
Y1 - 2023
N2 - A low- and intermediate-level radioactive waste repository contains various types of radionuclides and organic complexing agents. Their chemical interaction within the repository can lead to the formation of radionuclide-ligand complexes, influencing the limited retention behaviors of radionuclides. This study focuses on the sorption behavior of radionuclides on both engineered (concrete) and natural barriers (sedimentary rock and granite), as well as the prediction of sorption distribution coefficients (Kd) using support vector regression. Batch studies were conducted to determine the Kd values for three radionuclides (99Tc, 137Cs, and 238U) under different conditions, including pH, temperature, and the presence of organic ligands (such as ethylenediaminetetraacetic acid, nitrilotriacetic acid, and isosaccharinic acid). The Kd values for 238U exhibited a sharp decrease with increasing concentrations of organic ligands. In contrast, the Kd values for 99Tc showed only a slight reduction at higher organic ligand concentrations. Meanwhile, the Kd values for 137Cs remained relatively unchanged, regardless of the type and initial concentration of organic ligands. This suggests a high level of retention for 137Cs in the rock samples. The support vector regression model with a radial basis kernel function proved effective in predicting the Kd values under different experimental conditions. This enhancement in predicting accuracy contributes valuable insights into understanding the sorption processes involved in radionuclide behavior. Overall, this study advances our knowledge of radionuclide behavior on both engineered and natural barriers while providing a reliable prediction tool for estimating sorption distribution coefficients.
AB - A low- and intermediate-level radioactive waste repository contains various types of radionuclides and organic complexing agents. Their chemical interaction within the repository can lead to the formation of radionuclide-ligand complexes, influencing the limited retention behaviors of radionuclides. This study focuses on the sorption behavior of radionuclides on both engineered (concrete) and natural barriers (sedimentary rock and granite), as well as the prediction of sorption distribution coefficients (Kd) using support vector regression. Batch studies were conducted to determine the Kd values for three radionuclides (99Tc, 137Cs, and 238U) under different conditions, including pH, temperature, and the presence of organic ligands (such as ethylenediaminetetraacetic acid, nitrilotriacetic acid, and isosaccharinic acid). The Kd values for 238U exhibited a sharp decrease with increasing concentrations of organic ligands. In contrast, the Kd values for 99Tc showed only a slight reduction at higher organic ligand concentrations. Meanwhile, the Kd values for 137Cs remained relatively unchanged, regardless of the type and initial concentration of organic ligands. This suggests a high level of retention for 137Cs in the rock samples. The support vector regression model with a radial basis kernel function proved effective in predicting the Kd values under different experimental conditions. This enhancement in predicting accuracy contributes valuable insights into understanding the sorption processes involved in radionuclide behavior. Overall, this study advances our knowledge of radionuclide behavior on both engineered and natural barriers while providing a reliable prediction tool for estimating sorption distribution coefficients.
UR - http://www.scopus.com/inward/record.url?scp=85180130345&partnerID=8YFLogxK
U2 - 10.1155/2023/4760998
DO - 10.1155/2023/4760998
M3 - Article
AN - SCOPUS:85180130345
SN - 0363-907X
VL - 2023
JO - International Journal of Energy Research
JF - International Journal of Energy Research
M1 - 4760998
ER -