Hydrogen-assisted fatigue crack propagation in a pure BCC iron. Part I

Intergranular crack propagation at relatively low stress intensities

Yuhei Ogawa, Domas Birenis, Hisao Matsunaga, Osamu Takakuwa, Junichiro Yamabe, Øystein Prytz, Annett Thøgersen

研究成果: ジャーナルへの寄稿Conference article

3 引用 (Scopus)

抄録

The role of hydrogen on intergranular (IG) fracture in hydrogen-assisted fatigue crack growth (HAFCG) of a pure iron at low stress intensity was discussed in terms of the microscopic deformation structures near crack propagation paths. The main cause of IG fracture was assumed to be the hydrogen-enhanced dislocation structure evolution and subsequent microvoids formation along the grain boundaries. Additionally, the impact of such IG cracking on the macroscopic FCG rate was evaluated according to the dependency of IG fracture propensity on the hydrogen gas pressure. It was first demonstrated that the increased hydrogen pressure results in the larger area fraction of IG and corresponding faster FCG rate. Moreover, gaseous hydrogen environment also had a positive influence on the FCG rate due to the absence of oxygen and water vapor. The macroscopic crack propagation rate was controlled by the competition process of said positive and negative effects.

元の言語英語
記事番号03011
ジャーナルMATEC Web of Conferences
165
DOI
出版物ステータス出版済み - 5 25 2018
イベント12th International Fatigue Congress, FATIGUE 2018 - Poitiers Futuroscope, フランス
継続期間: 5 27 20186 1 2018

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Fatigue crack propagation
Hydrogen
Crack propagation
Iron
Steam
Water vapor
Grain boundaries
Gases
Oxygen

All Science Journal Classification (ASJC) codes

  • Chemistry(all)
  • Materials Science(all)
  • Engineering(all)

これを引用

Hydrogen-assisted fatigue crack propagation in a pure BCC iron. Part I : Intergranular crack propagation at relatively low stress intensities. / Ogawa, Yuhei; Birenis, Domas; Matsunaga, Hisao; Takakuwa, Osamu; Yamabe, Junichiro; Prytz, Øystein; Thøgersen, Annett.

:: MATEC Web of Conferences, 巻 165, 03011, 25.05.2018.

研究成果: ジャーナルへの寄稿Conference article

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AU - Ogawa, Yuhei

AU - Birenis, Domas

AU - Matsunaga, Hisao

AU - Takakuwa, Osamu

AU - Yamabe, Junichiro

AU - Prytz, Øystein

AU - Thøgersen, Annett

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AB - The role of hydrogen on intergranular (IG) fracture in hydrogen-assisted fatigue crack growth (HAFCG) of a pure iron at low stress intensity was discussed in terms of the microscopic deformation structures near crack propagation paths. The main cause of IG fracture was assumed to be the hydrogen-enhanced dislocation structure evolution and subsequent microvoids formation along the grain boundaries. Additionally, the impact of such IG cracking on the macroscopic FCG rate was evaluated according to the dependency of IG fracture propensity on the hydrogen gas pressure. It was first demonstrated that the increased hydrogen pressure results in the larger area fraction of IG and corresponding faster FCG rate. Moreover, gaseous hydrogen environment also had a positive influence on the FCG rate due to the absence of oxygen and water vapor. The macroscopic crack propagation rate was controlled by the competition process of said positive and negative effects.

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