High conduction neutron absorber to simulate fast reactor environment in an existing test reactor

A new metal matrix composite material has been developed to serve as a thermal neutron absorber for testing fast reactor fuels and materials in an existing pressurized water reactor. The performance of this material was evaluated by placing neutron fluence monitors within shrouded and unshrouded hol...

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Bibliographic Details
Published in:Journal of radioanalytical and nuclear chemistry 2014-10, Vol.302 (1), p.413-424
Main Authors: Guillen, Donna Post, Greenwood, Larry R., Parry, James R.
Format: Article
Language:English
Subjects:
Building materials
Chemistry
Chemistry and Materials Science
Comparative analysis
Diagnostic Radiology
fast reactor materials
Fast-to-thermal ratio
flux monitor
Hadrons
Heavy Ions
Inorganic Chemistry
neutron absorber
NEUTRON ABSORBERS
NEUTRON FLUENCE
NEUTRON FLUX
Nuclear Chemistry
Nuclear Physics
Nuclear reactors
Physical Chemistry
SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
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Summary:A new metal matrix composite material has been developed to serve as a thermal neutron absorber for testing fast reactor fuels and materials in an existing pressurized water reactor. The performance of this material was evaluated by placing neutron fluence monitors within shrouded and unshrouded holders and irradiating for up to four cycles. The monitor wires were analyzed by gamma and X-ray spectrometry to determine the activities of the activation products. Adjusted neutron fluences were calculated and grouped into three bins—thermal, epithermal, and fast—to evaluate the spectral shift created by the new material. A comparison of shrouded and unshrouded fluence monitors shows a thermal fluence decrease of ~11 % for the shielded monitors. Radioisotope activity and mass for each of the major activation products is given to provide insight into the evolution of thermal absorption cross-section during irradiation. The thermal neutron absorption capability of the composite material appears to diminish at total neutron fluence levels of ~8 × 10 25  n/m 2 . Calculated values for dpa in excess of 2.0 were obtained for two common structural materials (iron and nickel) of interest for future fast flux experiments.
ISSN:0236-5731
1588-2780
DOI:10.1007/s10967-014-3251-6