Molecular dynamics study of grain boundary and radiation effects on tritium population and diffusion in zirconium

Tritium population thermodynamics and transport kinetics critically define the tritium storage performance of zirconium tritides that can be used for a variety of nuclear applications including tritium-producing burnable absorber rods. Both thermodynamic and kinetic properties can be sensitive to gr...

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Veröffentlicht in:	Journal of nuclear materials 2023-05, Vol.578 (C), p.154376, Article 154376
Hauptverfasser:	Foster, M.E., Zhou, X.W.
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Sprache:	eng
Schlagworte:	Diffusion Hydrogen isotopes Molecular dynamics Radiation effects Zirconium
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container_title	Journal of nuclear materials
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creator	Foster, M.E. Zhou, X.W.
description	Tritium population thermodynamics and transport kinetics critically define the tritium storage performance of zirconium tritides that can be used for a variety of nuclear applications including tritium-producing burnable absorber rods. Both thermodynamic and kinetic properties can be sensitive to grain sizes of materials and can be significantly altered by irradiated defects during operation under the reactor environments. A thorough experimental characterization of how these properties evolve under different reactor conditions and different initial grain structures is extremely challenging. Here molecular dynamics simulations are used to investigate tritium population and diffusion in zirconium with and without different planar symmetric and asymmetric tilt grain boundaries and irradiated defects. We found that in addition to trapping tritium, the most significant effect of planar grain boundaries is to increase tritium diffusivity on the boundary plane. Furthermore, fine grain structures are found to mitigate the change of tritium diffusivity due to irradiated point defects as these point defects are likely to migrate to and sink at grain boundaries.
doi_str_mv	10.1016/j.jnucmat.2023.154376
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subjects	Diffusion Hydrogen isotopes Molecular dynamics Radiation effects Zirconium
title	Molecular dynamics study of grain boundary and radiation effects on tritium population and diffusion in zirconium
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