Peculiarity of hydrogen absorption in duplex steels: Phase-selective lattice swelling and stress evolution

Thomas Pogrielz; Matthias Eichinger; Adam Weiser; Juraj Todt; Anton Hohenwarter; Atacan Ascii; Baran Sarac; Dominik Brandl; Gerald Ressel; Milan Jary; Antonin Dlouhý; Gregor Karl Mori; Jozef Keckes

doi:10.1016/j.scriptamat.2024.116142

Peculiarity of hydrogen absorption in duplex steels: Phase-selective lattice swelling and stress evolution

Thomas Pogrielz, Matthias Eichinger, Adam Weiser, Juraj Todt, Anton Hohenwarter, Atacan Ascii, Baran Sarac, Dominik Brandl, Gerald Ressel, Milan Jary, Antonin Dlouhý, Gregor Karl Mori, Jozef Keckes

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Begutachtung

Abstract

Electrochemical hydrogen absorption in duplex steels is not fully understood. In this work, an in-situ synchrotron cross-sectional X-ray micro-diffraction analysis is performed on steel with comparable phase fractions of ferrite and austenite, coupled with electrolytic hydrogen charging. The results reveal that charging with a constant current density of 10 mA/cm² for 5 h leads to expanding the austenitic lattice to a depth of approximately 250 µm, up to ≥0.15 %. In contrast, the lattice parameter of the ferrite phase remains unchanged during this process. As the austenite expansion progresses, it generates different amounts of equivalent in-plane compressive stresses, which amount to approximately -150 and -450 MPa in the austenite and ferrite phases at the sample surface, respectively. Using a finite element model of grain interaction, this difference is qualitatively interpreted by mutual mechanical constraints between ferrite and austenite, as well as between the hydrogen-charged surface layer and the underlying material.

Originalsprache	Englisch
Aufsatznummer	116142
Seitenumfang	7
Fachzeitschrift	Scripta Materialia
Jahrgang	248.2024
Ausgabenummer	15 July
DOIs	https://doi.org/10.1016/j.scriptamat.2024.116142
Publikationsstatus	Elektronische Veröffentlichung vor Drucklegung. - 27 Apr. 2024

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Publisher Copyright:
© 2024 The Author(s)

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10.1016/j.scriptamat.2024.116142

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Pogrielz, T., Eichinger, M., Weiser, A., Todt, J., Hohenwarter, A., Ascii, A., Sarac, B., Brandl, D., Ressel, G., Jary, M., Dlouhý, A., Mori, G. K., & Keckes, J. (2024). Peculiarity of hydrogen absorption in duplex steels: Phase-selective lattice swelling and stress evolution. Scripta Materialia, 248.2024(15 July), Artikel 116142. Vorzeitige Online-Publikation. https://doi.org/10.1016/j.scriptamat.2024.116142

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abstract = "Electrochemical hydrogen absorption in duplex steels is not fully understood. In this work, an in-situ synchrotron cross-sectional X-ray micro-diffraction analysis is performed on steel with comparable phase fractions of ferrite and austenite, coupled with electrolytic hydrogen charging. The results reveal that charging with a constant current density of 10 mA/cm² for 5 h leads to expanding the austenitic lattice to a depth of approximately 250 µm, up to ≥0.15 %. In contrast, the lattice parameter of the ferrite phase remains unchanged during this process. As the austenite expansion progresses, it generates different amounts of equivalent in-plane compressive stresses, which amount to approximately -150 and -450 MPa in the austenite and ferrite phases at the sample surface, respectively. Using a finite element model of grain interaction, this difference is qualitatively interpreted by mutual mechanical constraints between ferrite and austenite, as well as between the hydrogen-charged surface layer and the underlying material.",

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T1 - Peculiarity of hydrogen absorption in duplex steels

T2 - Phase-selective lattice swelling and stress evolution

AU - Pogrielz, Thomas

AU - Eichinger, Matthias

AU - Weiser, Adam

AU - Todt, Juraj

AU - Hohenwarter, Anton

AU - Ascii, Atacan

AU - Sarac, Baran

AU - Brandl, Dominik

AU - Ressel, Gerald

AU - Jary, Milan

AU - Dlouhý, Antonin

AU - Mori, Gregor Karl

AU - Keckes, Jozef

PY - 2024/4/27

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N2 - Electrochemical hydrogen absorption in duplex steels is not fully understood. In this work, an in-situ synchrotron cross-sectional X-ray micro-diffraction analysis is performed on steel with comparable phase fractions of ferrite and austenite, coupled with electrolytic hydrogen charging. The results reveal that charging with a constant current density of 10 mA/cm² for 5 h leads to expanding the austenitic lattice to a depth of approximately 250 µm, up to ≥0.15 %. In contrast, the lattice parameter of the ferrite phase remains unchanged during this process. As the austenite expansion progresses, it generates different amounts of equivalent in-plane compressive stresses, which amount to approximately -150 and -450 MPa in the austenite and ferrite phases at the sample surface, respectively. Using a finite element model of grain interaction, this difference is qualitatively interpreted by mutual mechanical constraints between ferrite and austenite, as well as between the hydrogen-charged surface layer and the underlying material.

AB - Electrochemical hydrogen absorption in duplex steels is not fully understood. In this work, an in-situ synchrotron cross-sectional X-ray micro-diffraction analysis is performed on steel with comparable phase fractions of ferrite and austenite, coupled with electrolytic hydrogen charging. The results reveal that charging with a constant current density of 10 mA/cm² for 5 h leads to expanding the austenitic lattice to a depth of approximately 250 µm, up to ≥0.15 %. In contrast, the lattice parameter of the ferrite phase remains unchanged during this process. As the austenite expansion progresses, it generates different amounts of equivalent in-plane compressive stresses, which amount to approximately -150 and -450 MPa in the austenite and ferrite phases at the sample surface, respectively. Using a finite element model of grain interaction, this difference is qualitatively interpreted by mutual mechanical constraints between ferrite and austenite, as well as between the hydrogen-charged surface layer and the underlying material.

KW - Duplex steel

KW - Electrochemistry

KW - Hydrogen embrittlement

KW - Residual stress

KW - Synchrotron x-ray diffraction

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