Add to ORKGGross gamma-ray dose rates from six spent TRIGA fuel elements were measured and compared to calculated values as a means to validate the reported element burnups. A newly installed and functional gamma-ray detection subsystem of the In-Cell Examination System was used to perform the measurements and is described in some detail. The analytical methodology used to calculate the corresponding dose rates is presented along with the calculated values. Comparison of the measured and calculated dose rates for the TRIGA fuel elements indicates good agreement (less than a factor of 2 difference). The intent of the subsystem is to measure the gross gamma dose rate and correlate the measurement to a calculated dose rate based on the element s known bu...
Experimental and surface gamma irradiations of various small volume of bulk materials can be carried...
Nuclear energy is currently one of the world’s main sources of electricity. Closely connected to the...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...
Parametric burnup calculations are performed to estimate radionuclide isotopic mass and activity con...
[[abstract]]The purpose of this work is to establish a method for evaluating the burn-up values of t...
In the future, the demand for energy is predicted to grow and more countries plan to utilize nuclear...
In many countries, spent nuclear fuel is planned to be stored in a geological repository. Before th...
ABSTRACT This paper describes an evolutionary development process that will lead to spent fuel measu...
This report is a review of the status of nondestructive assay (NDA) methods used to determine burnup...
[[abstract]]A method is developed to verify the 235U content of TRIGA fresh fuel using gamma-ray spe...
In many countries, spent nuclear fuel is planned to be stored in a geological repository. Before th...
This work studies the reproducibility of passive gamma spectroscopy measurements for spent nuclear f...
As part of the Department of Energy`s spent nuclear fuel acceptance criteria, the mass of uranium an...
The characterization of spent fuel is of interest to the nuclear industry for in- and out-core appli...
Gamma spectroscopy and gamma emission tomography are two non-destructive measurement techniques for ...
Experimental and surface gamma irradiations of various small volume of bulk materials can be carried...
Nuclear energy is currently one of the world’s main sources of electricity. Closely connected to the...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...
Parametric burnup calculations are performed to estimate radionuclide isotopic mass and activity con...
[[abstract]]The purpose of this work is to establish a method for evaluating the burn-up values of t...
In the future, the demand for energy is predicted to grow and more countries plan to utilize nuclear...
In many countries, spent nuclear fuel is planned to be stored in a geological repository. Before th...
ABSTRACT This paper describes an evolutionary development process that will lead to spent fuel measu...
This report is a review of the status of nondestructive assay (NDA) methods used to determine burnup...
[[abstract]]A method is developed to verify the 235U content of TRIGA fresh fuel using gamma-ray spe...
In many countries, spent nuclear fuel is planned to be stored in a geological repository. Before th...
This work studies the reproducibility of passive gamma spectroscopy measurements for spent nuclear f...
As part of the Department of Energy`s spent nuclear fuel acceptance criteria, the mass of uranium an...
The characterization of spent fuel is of interest to the nuclear industry for in- and out-core appli...
Gamma spectroscopy and gamma emission tomography are two non-destructive measurement techniques for ...
Experimental and surface gamma irradiations of various small volume of bulk materials can be carried...
Nuclear energy is currently one of the world’s main sources of electricity. Closely connected to the...
With the reactor operation conditions - 4.3 wt% $^{235}U$ initial enrichment, burn-up 55,000 MWd/MTU...