Assessment of hydrogen embrittlement behavior in Al-Zn-Mg alloy through multi-modal 3D image-based simulation

• Published in: International journal of plasticity Vol. 174; p. 103897
• Main Authors: Fujihara, Hiro, Toda, Hiroyuki, Ebihara, Ken-ichi, Kobayashi, Masakazu, Mayama, Tsuyoshi, Hirayama, Kyosuke, Shimizu, Kazuyuki, Takeuchi, Akihisa, Uesugi, Masayuki
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.03.2024
• Subjects: 3D image-based simulation; Al-Zn-Mg alloys; Crystal plasticity finite element method; Diffraction contrast tomography; Hydrogen diffusion; Hydrogen embrittlement; X-ray tomography; Crystal plasticity finite element method; Hydrogen diffusion; Diffraction contrast tomography; Al-Zn-Mg alloys; X-ray tomography; 3D image-based simulation; Hydrogen embrittlement
• ISSN: 0749-6419
• DOI: 10.1016/j.ijplas.2024.103897

•An unprecedented multi-modal 3D image-based simulation was established to fully capture the actual distributions of stress and hydrogen.•Quasi-cleavage crack propagated in the region where the interfacial cohesive energy of precipitate was reduced by hydrogen.•A combination of hydrogen and applied stress led to nano-crack initiation and associated hydrogen embrittlement in Al-Zn-Mg alloy.•Dynamic hydrogen partitioning to precipitate dominates hydrogen embrittlement in Al-Zn-Mg alloy. Hydrogen can strongly embrittle aluminum alloys by accumulating at precipitate interface and triggering transgranular cracking, due to stress-driven hydrogen diffusion towards crack tip and grain boundaries. However, although mechanical features near crack tip and grain boundaries, and hydrogen diffusion/trapping processes have been extensively studied separately, very few quantitative information regarding the local interactions between hydrogen distribution and stress fields with full spatial complexity has been revealed. The present study attempts to fill this gap, by using a multi-modal three-dimensional image-based simulation that combines a crystal plasticity finite element method with hydrogen diffusion analysis, to fully capture the actual stress distribution and its effect on hydrogen distribution, and more importantly on cracking probability, near a real propagating hydrogen-induced crack. Stress-diffusion-trapping coupled simulations indicate the intergranular crack transitioned to a quasi-cleavage crack in the region where the interfacial cohesive energy of semi-coherent interface of the MgZn2 precipitate was reduced by hydrogen accumulation near the crack tip. The multi-modal three-dimensional image-based simulation used in the present study successfully bridged nanoscopic debonding and macroscopic hydrogen embrittlement fracture behavior. [Display omitted]