Effect of He seeding on hydrogen isotope permeation in tungsten by H-D mixed plasma exposure.

• Hydrogen (H) and deuterium (D) permeation fluxes for tungsten (W) by H-D mixed plasma were studied to clarify the hydrogen isotope effect on permeation by newly designed plasma driven permeation (PDP) device. • When single species of h or d was irradiated, the h permeation rate showed approximately 1.6 times as high as that of d. • H and d permeation fluxes were clearly reduced by seeding he in H-D mixed plasma. At lower temperature (∼723 K), the ratio of steady permeation fluxes of h and d was about 75 : 25, confirming the high permeation flux of h. • H and d permeation fluxes were reached almost unity at 923 K. Hydrogen (H) and deuterium (D) permeation fluxes for tungsten (W) by H-D mixed plasma were studied to clarify the hydrogen isotope effect on permeation by a newly designed plasma driven permeation (PDP) device at Shizuoka University. A mixed H-D plasma was produced by introducing H and D gasses with various ratios. The atomic ratio and permeation flux in the plasma were measured during the experiments. It was found that the H:D atomic ratio in the plasma was almost proportional to the introduced H:D gas ratio. When single species of H or D was irradiated, the H permeation rate showed approximately 1.6 times as high as that of D. Under H-D mixed plasma irradiation, the highest HD permeation rate was observed when the atomic ratio of H:D in the plasma was 50:50. In addition, the effect of He seeding on H-D mixed plasma driven permeation behavior was also evaluated. The recycling of hydrogen isotopes on the upstream side was enhanced due to the formation of He bubbles near the surface, which would prevent the dissolution of hydrogen isotopes into bulk W and enhance the reflection process during plasma exposure. H and D permeation fluxes were clearly reduced by seeding He in H-D mixed plasma. At lower temperature (∼723 K), the ratio of steady permeation fluxes of H and D was about 75 : 25, confirming the high permeation flux of H. These results have demonstrated a significant hydrogen isotope effect, even if He was seeded or not. As the temperature increased, H and D permeation fluxes approached unity at 923 K. This indicates that the hydrogen isotope effect was determined by the combination of recycling / reflection at or beneath the surface, which will be controlled by the temperature during plasma exposure. [ABSTRACT FROM AUTHOR]