https://orcid.org/0000-0002-0574-8822
References
- Jong Soon S, Cho HJ, Jung MY. A study on the application of CRUDTRAN code in primary systems of domestic pressurized heavy-water reactors for prediction of radiation source term. Nucl Eng Technol. 2017;49(3):638–644.
- YanZe H, XingCui L, Lan D, et al. A technique for the primary cooling circuit of the research type nuclear reactor. Nucl Eng Des. 2018;337:318–323.
- Camley GCW. The significance of corrosion products in water reactor coolant circuit. Prog Nucl Energy. 1985;16(10):41–72.
- Iva B, Martin B, Timo S. Start-up and shut-down water chemistries in pressurized water reactors. Espoo (Finland): VTT; 2012, (VTT-R-00699-12).
- Byung-Chul L, Seon-Byeong K, Jei-Kwon M. Equilibrium calculations for HyBRID decontamination of magnetite: effect of raw amount of CuSO4 on Cu2O formation. Nucl Eng Technol. 2020;52(11):2545–2551.
- Murphy ES, Holter GM. Technology, safety and costs of decommissioning reference light water reactors following postulated accidents. Richland (USA): U. S. Nuclear Regulatory Commission; 1982, (NUREG/CR-2601 Vol.1 ON: DE83004428).
- International Atomic Energy Agency. Decontamination of operational nuclear power plants. Vienna (Austria): International Atomic Energy Agency; 1981. (IAEA-TECDOC–248).
- Rolf R, Suat O, Jan K. Decontamination and steam generator chemical cleaning. Advanced nuclear technology international. Skultuna (Sweden); 2009. 2, Decontamination; 2-1-2-23.
- Sankaralingarm V, Valil SS, Therthala VP, et al. Behaviour of Ion exchange resins and corrosion inhibitors in dilute chemical decontamination. J Nucl Sci Technol. 1991;28(6):517–529.
- International Atomic Energy Agency. Application of Ion exchange processes for the treatment of radioactive waste and management of spent Ion exchangers. Vienna (Austria): International Atomic Energy Agency; 2002. (Technical Reports Series No. 408).
- Wangkyu C, Huijun W, Chonghun J, et al. Development of decommissioning, decontamination, and remediation technology for nuclear facilities: develo pment of advanced decontamination technology for nuclear facilities. Deajeon (Republic of Korea): Korea Atomic Energy Rese arch Institute; 2017. (KAERI/RR-4230/2016).
- Hee-Chul E, Jun-Young J, Sang-Yoon P, et al. Removal and decomposition of impurities in wastewater from the HyBRID decontamination process of the primary system in a nuclear power plant. JNFCWT. 2019;17(4):429–435.
- Junyoung J, Heechul E, Sangyoon P, et al. A study on the removal of impurities in a SP-HyBRID decontamination wastewater of the primary coolant system in a pressurized water reactor. J Radioanal Nucl Chem. 2018;318(1):1339–1345.
- Geun-Young P, Chang-Lak K. Chemical decontamination design for NPP decommissioning and considerations on its methodology. JNFCT. 2015;13(3):187–199.
- Maine Yankee RA. Decommissioning experience report detailed experiences 1997-2004. Illinois (USA): EPRI; 2004. (Technical Report 1011734)
- Baumgatner E, Torok J. Colloid particle behaviour in CAN-DECON decontamination. Ontario (Canada): Canadian Nuclear Association; 1982. (INIS-MF–9524).
- Keny SJ, Kumbhar AG, Venkateswaran G, et al. Radiation effects on the dissolution kinetics of mangnetite and hematite in EDTA- and NTA-based dilute chemical decontamination formulas. Radiat Phys Chem. 2005;72(4):475–482.
- Shailaja M, Narasimhan V. Mechanism of oxide scale removal during dilute chemical decontamination of carbon steel surfaces. J Nucl Sci Technol. 1993;30(6):524–532.
- Henning W, Yasin ED, Hermann T, et al. Silicon and iron as resource-efficient anode materials for ambient-temperature metal-air batteries: a review. Materials. 2019;12(2134):1–55.
- Mfandaidza H, Rob VH, Alison L. Mechanisms of formation of iron precipitates from ferrous solutions at high and low pH. Chem Eng Sci. 2008;63(6):1626–1635.