Penetration of deuterium into neutron-irradiated tungsten under plasma exposure

Miyuki Yajima; Yuji Hatano; Vladimir Kh Alimov; Takeshi Toyama; Tatsuya Kuwabara; Thomas Schwarz-Selinger; Yasuhisa Oya; Alexander V. Spitsyn; Noriyasu Ohno

doi:10.1088/1402-4896/ac2c20

Penetration of deuterium into neutron-irradiated tungsten under plasma exposure

Miyuki Yajima, Yuji Hatano^*, Vladimir Kh Alimov, Takeshi Toyama, Tatsuya Kuwabara, Thomas Schwarz-Selinger, Yasuhisa Oya, Alexander V. Spitsyn, Noriyasu Ohno

^*この論文の責任著者

研究推進機構水素同位体科学研究センター

研究成果: ジャーナルへの寄稿 › 学術論文 › 査読

5 被引用数 (Scopus)

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Hydrogen isotope trapping at lattice defects in neutron-irradiated tungsten (W), a leading candidate as plasma facing material, is an important problem determining tritium (T) inventory in a vacuum vessel of a future fusion reactor. In this study, W samples were irradiated with neutrons in the Belgium Reactor 2 at 563 K to 0.06 or 0.016 displacement per atom (dpa). After characterizing defects by positron lifetime measurements, deuterium (D) penetration under exposure to D plasma was examined at 563-773 K. Positron lifetime showed the presence of dislocations, monovacancies and relatively large vacancy clusters. These defects trapped D atoms with different values of binding energy. Dependence of D retention on plasma exposure temperature and damage level indicated that the concentrations of weak traps with smaller binding energy increased more significantly with damage level than those of strong traps.

本文言語	英語
論文番号	124042
ジャーナル	Physica Scripta T
巻	96
号	12
DOI	https://doi.org/10.1088/1402-4896/ac2c20
出版ステータス	出版済み - 2021/12

ASJC Scopus 主題領域

原子分子物理学および光学
数理物理学
凝縮系物理学

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10.1088/1402-4896/ac2c20

引用スタイル

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title = "Penetration of deuterium into neutron-irradiated tungsten under plasma exposure",

abstract = "Hydrogen isotope trapping at lattice defects in neutron-irradiated tungsten (W), a leading candidate as plasma facing material, is an important problem determining tritium (T) inventory in a vacuum vessel of a future fusion reactor. In this study, W samples were irradiated with neutrons in the Belgium Reactor 2 at 563 K to 0.06 or 0.016 displacement per atom (dpa). After characterizing defects by positron lifetime measurements, deuterium (D) penetration under exposure to D plasma was examined at 563-773 K. Positron lifetime showed the presence of dislocations, monovacancies and relatively large vacancy clusters. These defects trapped D atoms with different values of binding energy. Dependence of D retention on plasma exposure temperature and damage level indicated that the concentrations of weak traps with smaller binding energy increased more significantly with damage level than those of strong traps.",

author = "Miyuki Yajima and Yuji Hatano and Alimov, {Vladimir Kh} and Takeshi Toyama and Tatsuya Kuwabara and Thomas Schwarz-Selinger and Yasuhisa Oya and Spitsyn, {Alexander V.} and Noriyasu Ohno",

note = "Publisher Copyright: {\textcopyright} 2021 The Author(s). Published by IOP Publishing Ltd.",

year = "2021",

month = dec,

doi = "10.1088/1402-4896/ac2c20",

language = "英語",

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AU - Yajima, Miyuki

AU - Hatano, Yuji

AU - Alimov, Vladimir Kh

AU - Toyama, Takeshi

AU - Kuwabara, Tatsuya

AU - Schwarz-Selinger, Thomas

AU - Oya, Yasuhisa

AU - Spitsyn, Alexander V.

AU - Ohno, Noriyasu

PY - 2021/12

Y1 - 2021/12

N2 - Hydrogen isotope trapping at lattice defects in neutron-irradiated tungsten (W), a leading candidate as plasma facing material, is an important problem determining tritium (T) inventory in a vacuum vessel of a future fusion reactor. In this study, W samples were irradiated with neutrons in the Belgium Reactor 2 at 563 K to 0.06 or 0.016 displacement per atom (dpa). After characterizing defects by positron lifetime measurements, deuterium (D) penetration under exposure to D plasma was examined at 563-773 K. Positron lifetime showed the presence of dislocations, monovacancies and relatively large vacancy clusters. These defects trapped D atoms with different values of binding energy. Dependence of D retention on plasma exposure temperature and damage level indicated that the concentrations of weak traps with smaller binding energy increased more significantly with damage level than those of strong traps.

AB - Hydrogen isotope trapping at lattice defects in neutron-irradiated tungsten (W), a leading candidate as plasma facing material, is an important problem determining tritium (T) inventory in a vacuum vessel of a future fusion reactor. In this study, W samples were irradiated with neutrons in the Belgium Reactor 2 at 563 K to 0.06 or 0.016 displacement per atom (dpa). After characterizing defects by positron lifetime measurements, deuterium (D) penetration under exposure to D plasma was examined at 563-773 K. Positron lifetime showed the presence of dislocations, monovacancies and relatively large vacancy clusters. These defects trapped D atoms with different values of binding energy. Dependence of D retention on plasma exposure temperature and damage level indicated that the concentrations of weak traps with smaller binding energy increased more significantly with damage level than those of strong traps.

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DO - 10.1088/1402-4896/ac2c20

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Penetration of deuterium into neutron-irradiated tungsten under plasma exposure

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