Simulation of Charge Collection in a Boron-coated Straw Detector for Emerging Fuel Cycles

Abstract

Tristructural-isotropic (TRISO) fuel is currently one of the most mature fuel types for candidate advanced reactor types, namely pebble bed reactors (PBRs). In PBRs, TRISO-fueled pebbles can be re-introduced into the core several times before reaching their target burnup. Non-destructive techniques capable of assaying 235U mass in the pebble are therefore needed for nuclear material control and accountability during fuel recirculation. In this work, we have developed a new boron-coated straw (BCS) based neutron multiplicity counter (NMC) to estimate 235U mass in each pebble. BCS detectors are chosen for their inherent high insensitivity to gamma rays that will enable their use to assay also irradiated pebbles and high neutron detection efficiency, comparable to 3He detectors. The BCS-based NMC that we have designed was built by Proportional Technologies, Inc. (PTI) Houston, TX. In this work, we report the system-level simulation of the BCS-based NMC and the straw-level charge collection simulation coupled with a custom software to tally the detected pulse integral from the list mode energy deposited. We have developed a high-fidelity model of the NMC to simulate the response of a single straw detector to a 252Cf source. The simulated die-away time, single neutron count rate, and double neutron count rate agree well with measured values, with a relative difference within 0.4\%. The simulated charge spectrum agrees well with the measured one in the case of a round straw. We plan to use the NMC to perform active and passive interrogation of fresh and spent fuel pebbles.

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