Add to ORKGThose conducting waste management studies to reduce the potential for a nuclear criticality accident in a future geological repository must examine the quantities and distribution of fissile isotopes that are present in discharged boiling-water reactor (BWR) and pressurized-water reactor (PWR) spent nuclear fuel (SNF) scheduled for disposition. The major fissile isotopes present in LWR fuels that impact criticality safety are the nuclides, {sup 235}U, {sup 239}Pu, and {sup 24l}Pu. The sum of the quantities of these three nuclides, expressed as a percentage of the total amount of all U and Pu isotopes present in a batch of discharged fuel, determines the final enrichment of the fuel batch under consideration. The final enrichment provides an...
The purpose of this study is to provide some basic guidance regarding the criticality safety implica...
A neutronic analysis has been performed to assess a prospective utilization of light water reactor (...
High-level radioactive waste from nuclear fuels processing is stored in underground waste storage ta...
The fuel used in commercial nuclear power reactors is uranium, generally in the form of an oxide. Th...
The Materials Characterization Center (MCC) at Pacific Northwest Laboratory (PNL) provides well-char...
The United States (U.S.) currently utilizes a once-through fuel cycle where used nuclear fuel (UNF) ...
Safety analyses of criticality control systems for transportation packages include an assumption tha...
In 2005, the global inventory of spent nuclear fuel (SNF) is approximately 175,000 metric tonnes (sl...
Five fuel cycle options, about which little is known compared to more commonly known options, have b...
A methodology for performing and applying nuclear criticality safety calculations, for PWR spent nuc...
The US DOE Office of Fissile Material Disposition is examining options for placing fissile materials...
As a result of the end of the Cold War, the mission of the US Department of Energy (DOE) has shifted...
This document has been prepared to assist research reactor operators possessing spent fuel containin...
Used nuclear fuel disposition is a major nuclear waste management problem worldwide at the closing e...
Uranium-233 (U-233), a uranium isotope, is a fissionable material capable of fueling nuclear reactor...
The purpose of this study is to provide some basic guidance regarding the criticality safety implica...
A neutronic analysis has been performed to assess a prospective utilization of light water reactor (...
High-level radioactive waste from nuclear fuels processing is stored in underground waste storage ta...
The fuel used in commercial nuclear power reactors is uranium, generally in the form of an oxide. Th...
The Materials Characterization Center (MCC) at Pacific Northwest Laboratory (PNL) provides well-char...
The United States (U.S.) currently utilizes a once-through fuel cycle where used nuclear fuel (UNF) ...
Safety analyses of criticality control systems for transportation packages include an assumption tha...
In 2005, the global inventory of spent nuclear fuel (SNF) is approximately 175,000 metric tonnes (sl...
Five fuel cycle options, about which little is known compared to more commonly known options, have b...
A methodology for performing and applying nuclear criticality safety calculations, for PWR spent nuc...
The US DOE Office of Fissile Material Disposition is examining options for placing fissile materials...
As a result of the end of the Cold War, the mission of the US Department of Energy (DOE) has shifted...
This document has been prepared to assist research reactor operators possessing spent fuel containin...
Used nuclear fuel disposition is a major nuclear waste management problem worldwide at the closing e...
Uranium-233 (U-233), a uranium isotope, is a fissionable material capable of fueling nuclear reactor...
The purpose of this study is to provide some basic guidance regarding the criticality safety implica...
A neutronic analysis has been performed to assess a prospective utilization of light water reactor (...
High-level radioactive waste from nuclear fuels processing is stored in underground waste storage ta...