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Modified bibliography to fix thesis categorization and a markdown injection in abstract of ridley_preliminary_2017 which was confusing syntax highlighters
type = {{MS} {Nuclear} {Engineering} and {Engineering} {Physics}},
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title = {Photogrammetry, {Cloud} {Storage}, {Virtual} {Reality}, and {Augmented} {Reality} to {Guide} {Radiation} {Measurement} {Planning} and {Visualization} {PROCESS}},
title = {Preliminary {Results} of {Material} {Flow} {Controlled} {MSR} {Depletion} {Calculations}},
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volume = {116},
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url = {https://www.osti.gov/biblio/23050345},
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abstract = {A versatile, parallelizable Python 2.7 library was developed in order to simulate once-through molten salt reactor depletion in a realistic manner via the coupled neutronics/depletion code Serpent 2. Realistic in this sense entails two aspects: reactivity of the core, and oxidation potential of the fuel. The core reactivity should be maintained near zero as with any nuclear reactor. Gross reactivity control is provided by variations of the refuel rate of the reactor. Fine reactivity adjustments are expected to be done with control mechanisms in real-life power operation. The Python library developed allows a user to set bounds on the desired ke f f value. Fuel oxidation potential must be controlled for any liquid fueled reactor. As a simple example, consider this fission where the fuel becomes more oxidizing: UF\{sub 4\} → SrF\{sub 2\} + Xe + 2F\{sup -\} It can be shown using expected fission product oxidation state data that for these reactors, the fuel will become more oxidizing over time as a result of accumulation of excess fluoride ion. Addition of a reducing agent to reactor fuel will be necessary in the operation of molten salt reactors.},
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abstract = {A versatile, parallelizable Python 2.7 library was developed in order to simulate once-through molten salt reactor depletion in a realistic manner via the coupled neutronics/depletion code Serpent 2. Realistic in this sense entails two aspects: reactivity of the core, and oxidation potential of the fuel. The core reactivity should be maintained near zero as with any nuclear reactor. Gross reactivity control is provided by variations of the refuel rate of the reactor. Fine reactivity adjustments are expected to be done with control mechanisms in real-life power operation. The Python library developed allows a user to set bounds on the desired ke f f value. Fuel oxidation potential must be controlled for any liquid fueled reactor. As a simple example, consider this fission where the fuel becomes more oxidizing: UF_4 → SrF_2 + Xe + 2^- It can be shown using expected fission product oxidation state data that for these reactors, the fuel will become more oxidizing over time as a result of accumulation of excess fluoride ion. Addition of a reducing agent to reactor fuel will be necessary in the operation of molten salt reactors.},
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language = {English},
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urldate = {2024-06-03},
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booktitle = {Transactions of the {American} {Nuclear} {Society}},
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