Self-characterization of irradiation facility using synthetic multi-element standard for determination of k0-factors of seven radionuclides of interest

Phonesavanh lathdavong1, Ho Manh Dung2, Ho Van Doanh3, Tran Quang Thien4, Truong Truong Son5
1 Radiation and Nuclear Safety Office, Ministry of Education and Sports
2 Center for Nuclear Technologies (CNT) VINATOM 217 Nguyen Trai Street District 1, Ho Chi Minh City VIETNAM
3 Radiation and Environmental Safety Division, Ho Chi Minh City Nuclear Center, Vietnam Atomic Energy Institute.
4 Nuclear Research Institute (NRI)Add. 01 Nguyen Tu Luc St., Dalat, Vietnam
5 Department of Nuclear Physics Faculty of Physics, Ho Chi Minh City University of Education 280 An Duong Vuong Str., Ward 4, Dist. 5, Ho Chi Minh City

Main Article Content

Abstract

In this study, the k0 factors of 7 short and medium-lived radionuclides (i.e. 66Cu, 52V, 38Cl, 134mCs, 128I, 140La and 56Mn) were experimentally determined at the Dalat nuclear research reactor (DNRR). The synthetic multi-element standard (SMELS) samples were irradiated at Channel 7-1 installed at the DNRR. SMELS Type III contains Au and Zr, thus also allowing the self-characterization of the irradiation facility (i.e. the direct determination of f and a with only this material). The k0 factors of 7 short and medium-lived radionuclides obtained in this work are a good agreement with the reference k0 factors. The ratio values between the experimental and reference k0 values were 66Cu of 1.004, 52V of 1.004, 38Cl of 0.961 and 0.976 (1642.7 keV and 2167.4keV, respectively), 134mCs of 0.831, 128I of 1.022, 140La of 0.936, 0.955 and 0.955 (328.8 keV, 487.0 keV and 1596.2keV, respectively), 56Mn of 0.985 and 0.973 (846.8 keV and 1810.7keV, respectively). The radionuclides range of uncertainty values were lower than 7%. The present result indicates that the k0 factors can be determined by using synthetic multi-element standards (SMELS).

Article Details

References

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