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Irradiation temperature monitoring with SiC for RPV steel at low fluence

Jonas Vande Pitte, I. Uytdenhouwen, A. Gusarov, D. Del Serra, S. Van Dyck, Christophe Detavernier (UGent) and Johan Lauwaert (UGent)
(2021) JOURNAL OF NUCLEAR MATERIALS. 556.
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Abstract
Accurate knowledge of the irradiation temperature is a key concern in irradiations of reactor pressure vessel (RPV) steel. We report results of passive temperature monitoring of RPV steel with SiC. Two un-instrumented capsules containing RPV steel blocks were irradiated in Belgian Reactor 2, at SCK CEN in Belgium. Because un-instrumented capsules were used, the irradiation conditions (gamma heating and irradiation temperature) were calculated. To have experimental verification of the irradiation conditions each capsule contained a passive silicon carbide (SiC) temperature monitor. After irradiation the resistivity and the radiation-induced swelling (lattice parameter) is measured using x-ray diffraction (XRD). These measurements were repeated after annealing treatments to determine the peak irradiation temperature. The best method to determine the peak irradiation temperature with the lowest uncertainty in this study was the resistivity technique. Although lattice parameter measurements could be improved by using ma-terial without preferential orientation. Tensile tests of the RPV blocks were compared to a large available database of RPV material with the proper sensitivity towards neutron fluence and irradiation temperature to find the irradiation temperature of the RPV steel. The data showed a discrepancy between the tem-perature obtained from SiC and the temperature obtained from tensile tests. The temperature differences were discussed and rationalized by finite element modelling with respect to uncertainties in the helium gap between the capsule and the RPV steel block. The aluminium holder accounted for the tempera -ture difference and the use of a steel holder is recommended for future similar irradiations to minimize the temperature difference between SiC and tensile specimens. In-depth analysis showed that when the irradiation temperature dropped at the end of the irradiation for a considerable time, the SiC tempera -ture monitor had a memory effect. In this case the post-irradiation resistivity analysis showed two peak irradiation temperatures with a region of constant resistivity between the two.
Keywords
Nuclear and High Energy Physics, General Materials Science, Nuclear Energy and Engineering, Silicon carbide, RPV Steel, Irradiation temperature, Resistivity, Lattice parameter, SILICON-CARBIDE, FUEL PERFORMANCE, ALLOY

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MLA
Vande Pitte, Jonas, et al. “Irradiation Temperature Monitoring with SiC for RPV Steel at Low Fluence.” JOURNAL OF NUCLEAR MATERIALS, vol. 556, 2021, doi:10.1016/j.jnucmat.2021.153192.
APA
Vande Pitte, J., Uytdenhouwen, I., Gusarov, A., Del Serra, D., Van Dyck, S., Detavernier, C., & Lauwaert, J. (2021). Irradiation temperature monitoring with SiC for RPV steel at low fluence. JOURNAL OF NUCLEAR MATERIALS, 556. https://doi.org/10.1016/j.jnucmat.2021.153192
Chicago author-date
Vande Pitte, Jonas, I. Uytdenhouwen, A. Gusarov, D. Del Serra, S. Van Dyck, Christophe Detavernier, and Johan Lauwaert. 2021. “Irradiation Temperature Monitoring with SiC for RPV Steel at Low Fluence.” JOURNAL OF NUCLEAR MATERIALS 556. https://doi.org/10.1016/j.jnucmat.2021.153192.
Chicago author-date (all authors)
Vande Pitte, Jonas, I. Uytdenhouwen, A. Gusarov, D. Del Serra, S. Van Dyck, Christophe Detavernier, and Johan Lauwaert. 2021. “Irradiation Temperature Monitoring with SiC for RPV Steel at Low Fluence.” JOURNAL OF NUCLEAR MATERIALS 556. doi:10.1016/j.jnucmat.2021.153192.
Vancouver
1.
Vande Pitte J, Uytdenhouwen I, Gusarov A, Del Serra D, Van Dyck S, Detavernier C, et al. Irradiation temperature monitoring with SiC for RPV steel at low fluence. JOURNAL OF NUCLEAR MATERIALS. 2021;556.
IEEE
[1]
J. Vande Pitte et al., “Irradiation temperature monitoring with SiC for RPV steel at low fluence,” JOURNAL OF NUCLEAR MATERIALS, vol. 556, 2021.
@article{8716829,
  abstract     = {{Accurate knowledge of the irradiation temperature is a key concern in irradiations of reactor pressure vessel (RPV) steel. We report results of passive temperature monitoring of RPV steel with SiC. Two un-instrumented capsules containing RPV steel blocks were irradiated in Belgian Reactor 2, at SCK CEN in Belgium. Because un-instrumented capsules were used, the irradiation conditions (gamma heating and irradiation temperature) were calculated. To have experimental verification of the irradiation conditions each capsule contained a passive silicon carbide (SiC) temperature monitor. After irradiation the resistivity and the radiation-induced swelling (lattice parameter) is measured using x-ray diffraction (XRD). These measurements were repeated after annealing treatments to determine the peak irradiation temperature. The best method to determine the peak irradiation temperature with the lowest uncertainty in this study was the resistivity technique. Although lattice parameter measurements could be improved by using ma-terial without preferential orientation. Tensile tests of the RPV blocks were compared to a large available database of RPV material with the proper sensitivity towards neutron fluence and irradiation temperature to find the irradiation temperature of the RPV steel. The data showed a discrepancy between the tem-perature obtained from SiC and the temperature obtained from tensile tests. The temperature differences were discussed and rationalized by finite element modelling with respect to uncertainties in the helium gap between the capsule and the RPV steel block. The aluminium holder accounted for the tempera -ture difference and the use of a steel holder is recommended for future similar irradiations to minimize the temperature difference between SiC and tensile specimens. In-depth analysis showed that when the irradiation temperature dropped at the end of the irradiation for a considerable time, the SiC tempera -ture monitor had a memory effect. In this case the post-irradiation resistivity analysis showed two peak irradiation temperatures with a region of constant resistivity between the two.}},
  articleno    = {{153192}},
  author       = {{Vande Pitte, Jonas and Uytdenhouwen, I. and Gusarov, A. and Del Serra, D. and Van Dyck, S. and Detavernier, Christophe and Lauwaert, Johan}},
  issn         = {{0022-3115}},
  journal      = {{JOURNAL OF NUCLEAR MATERIALS}},
  keywords     = {{Nuclear and High Energy Physics,General Materials Science,Nuclear Energy and Engineering,Silicon carbide,RPV Steel,Irradiation temperature,Resistivity,Lattice parameter,SILICON-CARBIDE,FUEL PERFORMANCE,ALLOY}},
  language     = {{eng}},
  pages        = {{9}},
  title        = {{Irradiation temperature monitoring with SiC for RPV steel at low fluence}},
  url          = {{http://doi.org/10.1016/j.jnucmat.2021.153192}},
  volume       = {{556}},
  year         = {{2021}},
}
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