Identification of impact of minor actinide addition on burnup process and heavy nuclide evolution in UN-PuN fueled small modular gas-cooled fast reactors

Authors

DOI:

https://doi.org/10.15587/1729-4061.2026.352394

Keywords:

conversion ratio, GFR, COREBN, k-eff, minor actinide, radiopharmaceutical, SMR, transmutation

Abstract

The object of this study is a small modular gas-cooled fast reactor (GFR) fuelled by UN-PuN with minor actinides (MA) addition. The problem solved in this study is the identification of the impact of MA addition on the criticality, fuel burnup stability, and nuclear waste transmutation of the small modular GFR. The parameters studied include k-eff, macroscopic cross-section, conversion ratio (CR), heavy nuclides inventory, and the probability of radiopharmaceutical isotope production. The study was conducted using SRAC-COREBN computational analysis, and the MA used in this study were Pa-231, Am-241, and Np-237. The results obtained that the MA addition, on average, results in a decrease in k-eff, the magnitude of which depends on the type and concentration of MA. Macroscopic cross-section analysis reveals shifts in values, such as an increase in the Macroscopic cross-section absorption, particularly in the case of Am-241. Then, an increase in the macroscopic cross-section of fission is passed at high energies. The CR > 1 and inversion ratio of heavy nuclide approximately are observed at 50% in all configurations. Furthermore, the evolution of fission products such as Tc-99, Rh-105, and I-135 suggests the chance production of radiopharmaceutical isotope. Interpretation of the results show that adding MA effect k-eff and CR because isotopes such as Am-241, Np-237, and Pa-231 actively participate in fission and conversion of fissile material using fast neutron spectrum. A key feature of obtained results is a stable burnup profile, where the MA effectively functions in target transmutation without disrupting the consumption of the primary fissile fuel. These findings could be a technical basis for supporting national energy security and sustainable nuclear waste management.

Author Biographies

Mila Hidayatul Aula, Universitas Jember

Master

Department of Physics

Ratna Dewi Syarifah, Universitas Jember

Doctor of Physics Sciences

Department of Physics

Ahmad Haris Rasidi, Universitas Jember

Bachelor of Physics

Department of Physics Sciences

Abdulloh Hasan Shodiq, Universitas Jember

Bachelor of Physics

Department of Physics

Muhammad Husein Shodiq, Universitas Jember

Bachelor of Physics

Department of Physics

Bekti Palupi

Master

Department of Chemical Engineering

Nuri Trianti, National Research and Innovation Agency

Doctor of Physics Sciences

Department of Nuclear Reactor Technology

Zaki Su’ud, Bandung Institute of Technology

Professor

Department of Physics

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Identification of impact of minor actinide addition on burnup process and heavy nuclide evolution in UN-PuN fueled small modular gas-cooled fast reactors

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Published

2026-02-27

How to Cite

Aula, M. H., Syarifah, R. D., Rasidi, A. H., Shodiq, A. H., Shodiq, M. H., Palupi, B., Trianti, N., & Su’ud, Z. (2026). Identification of impact of minor actinide addition on burnup process and heavy nuclide evolution in UN-PuN fueled small modular gas-cooled fast reactors. Eastern-European Journal of Enterprise Technologies, 1(8 (139), 37–48. https://doi.org/10.15587/1729-4061.2026.352394

Issue

Vol. 1 No. 8 (139) (2026): Energy-saving technologies and equipment

Section

Energy-saving technologies and equipment

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Copyright (c) 2026 Mila Hidayatul Aula, Ratna Dewi Syarifah, Ahmad Haris Rasidi, Abdulloh Hasan Shodiq, Muhammad Husein Shodiq, Bekti Palupi, Nuri Trianti, Zaki Su’ud

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