Hydrogen trapping and diffusion in polycrystalline nickel: The spectrum of grain boundary segregation
Abstract
Hydrogen as an interstitial solute at grain boundaries (GBs) can have a catastrophic impact on the mechanical properties of many metals. Despite the global research effort, the underlying hydrogen-GB interactions in polycrystals remain inadequately understood. In this study, using Voronoi tessellations and atomistic simulations, we elucidate the hydrogen segregation energy spectrum at the GBs of polycrystalline nickel by exploring all the topologically favorable segregation sites. Three distinct peaks in the energy spectrum are identified, corresponding to different structural fingerprints. The first peak (−0.205 eV) represents the most favorable segregation sites at GB core, while the second and third peaks account for the sites at GB surface. By incorporating a thermodynamic model, the spectrum enables the determination of the equilibrium hydrogen concentrations at GBs, unveiling a remarkable two to three orders of magnitude increase compared to the bulk hydrogen concentration reported in experimental studies. The identified structures from the GB spectrum exhibit vastly different behaviors in hydrogen segregation and diffusion, with the low-barrier channels inside GB core contributing to short-circuit diffusion, while the high energy gaps between GB and neighboring lattice serving as on-plane diffusion barriers. Mean square displacement analysis further confirms the findings, and shows that the calculated GB diffusion coefficient is three orders of magnitude greater than that of lattice. The present study has a significant implication for practical applications since it offers a tool to bridge the gap between atomic-scale interactions and macroscopic behaviors in engineering materials.
Copyright and License
© 2024 Published by Elsevier Ltd on behalf of The editorial office of Journal of Materials Science & Technology Under a Creative Commons license.
Acknowledgement
This work was financially supported by the Research Council of Norway under the M-HEAT project (No. 294689) and the HyLINE Project (No. 294739). All simulation resources are provided by the Norwegian Metacenter for Computational Science (Nos. NN9110K and NN9391K).
Contributions
The project was planned and supervised by Z.Z. The simulation design and data analysis were performed by Y.D. All authors participated in the discussion and co-wrote the paper.
Yu Ding: Visualization, Formal analysis, Writing – original draft. Haiyang Yu: Writing – original draft. Meichao Lin: Writing – original draft. Michael Ortiz: Writing – original draft. Senbo Xiao: Writing – original draft. Jianying He: Writing – original draft. Zhiliang Zhang: Project administration, Supervision, Writing – original draft.
Data Availability
The data that support the findings of this study are available from the corresponding authors upon request.
Conflict of Interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
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Additional details
- The Research Council of Norway
- 294689
- The Research Council of Norway
- 294739
- Caltech groups
- GALCIT