Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations

H. Kurishita; S. Kobayashi; K. Nakai; T. Ogawa; A. Hasegawa; K. Abe; H. Arakawa; S. Matsuo; T. Takida; K. Takebe; M. Kawai; N. Yoshida

doi:10.1016/j.jnucmat.2008.02.055

Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations

H. Kurishita, S. Kobayashi, K. Nakai, T. Ogawa, A. Hasegawa, K. Abe, H. Arakawa, S. Matsuo, T. Takida, K. Takebe, M. Kawai, N. Yoshida

工学研究科・量子エネルギー工学専攻

研究成果: Article › 査読

176 被引用数 (Scopus)

抄録

W-(0.25-0.8)wt%TiC with equiaxed grain sizes of 50-200 nm and nearly full density of 99% was fabricated utilizing mechanical alloying (MA) in different gas atmospheres of H₂, Ar and N₂ and hot isostatic pressing. Microstructural and mechanical property examinations were conducted before and after irradiations with neutrons at 600 °C to 2 × 10²⁴ n/m² and 3 MeV He-ions at 550 °C to 2 × 10²³ He/m². It is found that TiC additions and MA atmospheres significantly affect grain refinement and baseline mechanical properties. The room-temperature fracture strength takes a maximum of 2 GPa for W-(0.25-0.5)%TiC with MA in H₂ (W-(0.25-0.5)TiC-H₂). At 1400-1700 °C superplastic behavior occurs for W-0.5TiC-H₂, but is suppressed for W-0.5TiC-Ar. No neutron irradiation hardening is recognized in W-0.5TiC-H₂ and W-0.5TiC-Ar. The critical fluence for surface exfoliation by He irradiation for W-0.3TiC-H₂ is more than 10 times as large as that for commercially available W materials. These results suggest that ultra-fine grained W-TiC is capable of improved performance as the spallation neutron source solid target.

本文言語	English
ページ（範囲）	34-40
ページ数	7
ジャーナル	Journal of Nuclear Materials
巻	377
号	1
DOI	https://doi.org/10.1016/j.jnucmat.2008.02.055
出版ステータス	Published - 2008 6月 30

ASJC Scopus subject areas

核物理学および高エネルギー物理学
材料科学（全般）
原子力エネルギーおよび原子力工学

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Kurishita, H., Kobayashi, S., Nakai, K., Ogawa, T., Hasegawa, A., Abe, K., Arakawa, H., Matsuo, S., Takida, T., Takebe, K., Kawai, M., & Yoshida, N. (2008). Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations. Journal of Nuclear Materials, 377(1), 34-40. https://doi.org/10.1016/j.jnucmat.2008.02.055

Kurishita, H, Kobayashi, S, Nakai, K, Ogawa, T, Hasegawa, A, Abe, K, Arakawa, H, Matsuo, S, Takida, T, Takebe, K, Kawai, M & Yoshida, N 2008, 'Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations', Journal of Nuclear Materials, vol. 377, no. 1, pp. 34-40. https://doi.org/10.1016/j.jnucmat.2008.02.055

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title = "Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations",

abstract = "W-(0.25-0.8)wt%TiC with equiaxed grain sizes of 50-200 nm and nearly full density of 99% was fabricated utilizing mechanical alloying (MA) in different gas atmospheres of H2, Ar and N2 and hot isostatic pressing. Microstructural and mechanical property examinations were conducted before and after irradiations with neutrons at 600 °C to 2 × 1024 n/m2 and 3 MeV He-ions at 550 °C to 2 × 1023 He/m2. It is found that TiC additions and MA atmospheres significantly affect grain refinement and baseline mechanical properties. The room-temperature fracture strength takes a maximum of 2 GPa for W-(0.25-0.5)%TiC with MA in H2 (W-(0.25-0.5)TiC-H2). At 1400-1700 °C superplastic behavior occurs for W-0.5TiC-H2, but is suppressed for W-0.5TiC-Ar. No neutron irradiation hardening is recognized in W-0.5TiC-H2 and W-0.5TiC-Ar. The critical fluence for surface exfoliation by He irradiation for W-0.3TiC-H2 is more than 10 times as large as that for commercially available W materials. These results suggest that ultra-fine grained W-TiC is capable of improved performance as the spallation neutron source solid target.",

author = "H. Kurishita and S. Kobayashi and K. Nakai and T. Ogawa and A. Hasegawa and K. Abe and H. Arakawa and S. Matsuo and T. Takida and K. Takebe and M. Kawai and N. Yoshida",

note = "Funding Information: The present work was partly supported by Grant-in-Aid for Scientific Research (B) (#19360412), Japan Society for the Promotion of Science (JSPS), which is greatly appreciated. ",

year = "2008",

month = jun,

day = "30",

doi = "10.1016/j.jnucmat.2008.02.055",

language = "English",

volume = "377",

pages = "34--40",

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T1 - Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations

AU - Kurishita, H.

AU - Kobayashi, S.

AU - Nakai, K.

AU - Ogawa, T.

AU - Hasegawa, A.

AU - Abe, K.

AU - Arakawa, H.

AU - Matsuo, S.

AU - Takida, T.

AU - Takebe, K.

AU - Kawai, M.

AU - Yoshida, N.

N1 - Funding Information: The present work was partly supported by Grant-in-Aid for Scientific Research (B) (#19360412), Japan Society for the Promotion of Science (JSPS), which is greatly appreciated.

PY - 2008/6/30

Y1 - 2008/6/30

N2 - W-(0.25-0.8)wt%TiC with equiaxed grain sizes of 50-200 nm and nearly full density of 99% was fabricated utilizing mechanical alloying (MA) in different gas atmospheres of H2, Ar and N2 and hot isostatic pressing. Microstructural and mechanical property examinations were conducted before and after irradiations with neutrons at 600 °C to 2 × 1024 n/m2 and 3 MeV He-ions at 550 °C to 2 × 1023 He/m2. It is found that TiC additions and MA atmospheres significantly affect grain refinement and baseline mechanical properties. The room-temperature fracture strength takes a maximum of 2 GPa for W-(0.25-0.5)%TiC with MA in H2 (W-(0.25-0.5)TiC-H2). At 1400-1700 °C superplastic behavior occurs for W-0.5TiC-H2, but is suppressed for W-0.5TiC-Ar. No neutron irradiation hardening is recognized in W-0.5TiC-H2 and W-0.5TiC-Ar. The critical fluence for surface exfoliation by He irradiation for W-0.3TiC-H2 is more than 10 times as large as that for commercially available W materials. These results suggest that ultra-fine grained W-TiC is capable of improved performance as the spallation neutron source solid target.

AB - W-(0.25-0.8)wt%TiC with equiaxed grain sizes of 50-200 nm and nearly full density of 99% was fabricated utilizing mechanical alloying (MA) in different gas atmospheres of H2, Ar and N2 and hot isostatic pressing. Microstructural and mechanical property examinations were conducted before and after irradiations with neutrons at 600 °C to 2 × 1024 n/m2 and 3 MeV He-ions at 550 °C to 2 × 1023 He/m2. It is found that TiC additions and MA atmospheres significantly affect grain refinement and baseline mechanical properties. The room-temperature fracture strength takes a maximum of 2 GPa for W-(0.25-0.5)%TiC with MA in H2 (W-(0.25-0.5)TiC-H2). At 1400-1700 °C superplastic behavior occurs for W-0.5TiC-H2, but is suppressed for W-0.5TiC-Ar. No neutron irradiation hardening is recognized in W-0.5TiC-H2 and W-0.5TiC-Ar. The critical fluence for surface exfoliation by He irradiation for W-0.3TiC-H2 is more than 10 times as large as that for commercially available W materials. These results suggest that ultra-fine grained W-TiC is capable of improved performance as the spallation neutron source solid target.

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SN - 0022-3115

VL - 377

SP - 34

EP - 40

JO - Journal of Nuclear Materials

JF - Journal of Nuclear Materials

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ER -

Development of ultra-fine grained W-(0.25-0.8)wt%TiC and its superior resistance to neutron and 3 MeV He-ion irradiations

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