A Comparison of Near Surface Precipitation in Tungsten Alloys Due to High Flux Plasma Exposure
Abstract not provided.
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Jump to search filtersA multi-technique analysis of deuterium trapping and near-surface precipitate growth in plasma-exposed tungsten
Journal of Applied Physics
We examine how deuterium becomes trapped in plasma-exposed tungsten and forms near-surface platelet-shaped precipitates. How these bubbles nucleate and grow, as well as the amount of deuterium trapped within, is crucial for interpreting the experimental database. Here, we use a combined experimental/theoretical approach to provide further insight into the underlying physics. With the Tritium Plasma Experiment, we exposed a series of ITER-gradetungsten samples to high flux D plasmas (up to 1.5 × 1022 m-2 s-1) at temperatures ranging between 103 and 554 °C. Retention of deuterium trapped in the bulk, assessed through thermal desorption spectrometry, reached a maximum at 230 °C and diminished rapidly thereafter for T > 300 °C. Post-mortem examination of the surfaces revealed non-uniform growth of bubbles ranging in diameter between 1 and 10 μm over the surface with a clear correlation with grain boundaries. Electron back-scattering diffraction maps over a large area of the surface confirmed this dependence; grains containing bubbles were aligned with a preferred slip vector along the <111> directions. Focused ion beam profiles suggest that these bubbles nucleated as platelets at depths of 200 nm–1 μm beneath the surface and grew as a result of expansion of sub-surface cracks. Furthermore, to estimate the amount of deuterium trapped in these defects relative to other sites within the material, we applied a continuum-scale treatment of hydrogen isotope precipitation. Additionally, we propose a straightforward model of near-surface platelet expansion that reproduces bubble sizes consistent with our measurements. For the tungsten microstructure considered here, we find that bubbles would only weakly affect migration of D into the material, perhaps explaining why deep trapping was observed in prior studies with plasma-exposed neutron-irradiated specimens. We foresee no insurmountable issues that would prevent the theoretical framework developed here from being extended to a broader range of systems where precipitation of insoluble gases in ion beam or plasma-exposed metals is of interest.
Mechanical Properties of PVDF Latex Skin Layers by Tension Induced Wrinkles
Abstract not provided.
Dependence of deuterium retention and surface morphology on tungsten microstructure after high-flux plasma exposure
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Characterization of the Electrical Properties of Individual Multi-Walled Carbon Nanotubes
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Nanoscale Optimization of Ultrasonic Dispersion of Multi-Walled Carbon Nanotubes in Polyelectrolyte Aqueous Solution
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Nanoscale Optimization of Ultrasonic Dispersion of Multi-Walled Carbon Nanotubes in Polyelectrolyte Aqueous Solution
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Characterization of the Electrical Properties of Single Multi-Walled Carbon Nanotubes
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Characterization of helium bubble growth in tungsten exposed to low-flux plasmas
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Copy of Deformation and Delamination in Polymer Metal Thin Film Structures (Invited)
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Nanoimprinting and characterization of thermoresponsive shape memory polymer
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