Distinct impacts of hydrogen and carbon on thermally activated dislocation motion in Fe-Cr-Ni austenitic steel

Haruki Nishida; Yuhei Ogawa; Akinobu Shibata

doi:10.1016/j.scriptamat.2025.117111

論文 Distinct impacts of hydrogen and carbon on thermally activated dislocation motion in Fe-Cr-Ni austenitic steel

Haruki Nishida (National Institute for Materials Science) ; Yuhei Ogawa (National Institute for Materials Science) ; Akinobu Shibata (National Institute for Materials Science)

Nishida et al. (2026)_Scripta Materialia.pdf

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Haruki Nishida, Yuhei Ogawa, Akinobu Shibata. Distinct impacts of hydrogen and carbon on thermally activated dislocation motion in Fe-Cr-Ni austenitic steel. Scripta Materialia. 2025, 273 (), 117111. https://doi.org/10.1016/j.scriptamat.2025.117111

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(abstract)

Plastic flow behavior and strain rate sensitivity, S, of Fe-15Cr-15Ni (mass%) austenitic steel, alloyed with either hydrogen or carbon, were evaluated by tensile and stress relaxation tests at ambient temperature. The effects of these two interstitial elements on solid solution-hardening and thermally activated dislocation motion were compared in terms of Haasen plot—S versus flow stress. Both hydrogen and carbon exhibited solid solution-hardening of the same order of magnitude, increasing S proportionally with their concentrations. However, their ability to increase S was distinct. Hydrogen caused a much steeper increase in S, acting as extremely localized obstacles resisting dislocation motion. In contrast, despite exhibiting comparable solid solution-hardening, carbon led to an order of magnitude smaller increase in S than hydrogen. This result demonstrates a relatively long-range and less rate-sensitive nature of carbon, which is totally different from hydrogen in its obstacle character.

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