TY - JOUR
T1 - Comparison of deuterium retention for ion-irradiated and neutron-irradiated tungsten
AU - Oya, Yasuhisa
AU - Shimada, Masashi
AU - Kobayashi, Makoto
AU - Oda, Takuji
AU - Hara, Masanori
AU - Watanabe, Hideo
AU - Hatano, Yuji
AU - Calderoni, Pattrick
AU - Okuno, Kenji
PY - 2011
Y1 - 2011
N2 - The behavior of D retention for Fe 2+-irradiated tungsten with a damage of 0.025-3 dpa was compared with that for neutron-irradiated tungsten with 0.025 dpa. The D 2 thermal desorption spectroscopy (TDS) spectra for Fe 2+-irradiated tungsten consisted of two desorption stages at 450 and 550 K, while that for neutron-irradiated tungsten was composed of three stages and an addition desorption stage was found at 750 K. The desorption rate of the major desorption stage at 550 K increased as the displacement damage increased due to Fe 2+ irradiation increasing. In addition, the first desorption stage at 450 K was found only for damaged samples. Therefore, the second stage would be based on intrinsic defects or vacancy produced by Fe 2+ irradiation, and the first stage should be the accumulation of D in mono-vacancy and the activation energy would be relatively reduced, where the dislocation loop and vacancy is produced. The third one was found only for neutron irradiation, showing the D trapping by a void or vacancy cluster, and the diffusion effect is also contributed to by the high full-width at half-maximum of the TDS spectrum. Therefore, it can be said that the D 2 TDS spectra for Fe 2+-irradiated tungsten cannot represent that for the neutron-irradiated one, indicating that the deuterium trapping and desorption mechanism for neutron-irradiated tungsten is different from that for the ion-irradiated one.
AB - The behavior of D retention for Fe 2+-irradiated tungsten with a damage of 0.025-3 dpa was compared with that for neutron-irradiated tungsten with 0.025 dpa. The D 2 thermal desorption spectroscopy (TDS) spectra for Fe 2+-irradiated tungsten consisted of two desorption stages at 450 and 550 K, while that for neutron-irradiated tungsten was composed of three stages and an addition desorption stage was found at 750 K. The desorption rate of the major desorption stage at 550 K increased as the displacement damage increased due to Fe 2+ irradiation increasing. In addition, the first desorption stage at 450 K was found only for damaged samples. Therefore, the second stage would be based on intrinsic defects or vacancy produced by Fe 2+ irradiation, and the first stage should be the accumulation of D in mono-vacancy and the activation energy would be relatively reduced, where the dislocation loop and vacancy is produced. The third one was found only for neutron irradiation, showing the D trapping by a void or vacancy cluster, and the diffusion effect is also contributed to by the high full-width at half-maximum of the TDS spectrum. Therefore, it can be said that the D 2 TDS spectra for Fe 2+-irradiated tungsten cannot represent that for the neutron-irradiated one, indicating that the deuterium trapping and desorption mechanism for neutron-irradiated tungsten is different from that for the ion-irradiated one.
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U2 - 10.1088/0031-8949/2011/T145/014050
DO - 10.1088/0031-8949/2011/T145/014050
M3 - Conference article
AN - SCOPUS:84857604242
SN - 0281-1847
VL - T145
JO - Physica Scripta T
JF - Physica Scripta T
M1 - 014050
T2 - 13th International Workshop on Plasma-Facing Materials and Components for Fusion Applications, PFMC-13 and 1st International Conference on Fusion Energy Materials Science, FEMaS-1
Y2 - 9 May 2011 through 13 May 2011
ER -