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MM: Fachverband Metall- und Materialphysik

MM 34: Hydrogen in Materials I

MM 34.6: Vortrag

Donnerstag, 12. März 2026, 17:00–17:15, SCH/A215

Hydrogen Solution Energies at Microstructural Defects in Ferritic Steels — •Onur Can Şen^1,2,3, Santiago Benito², Sebastian Weber², and Rebecca Janisch³ — ¹Max Planck Institute for Sustainable Materials, Germany — ²Institute for Materials, Chair of Materials Technology, Ruhr-University Bochum, Germany — ³ICAMS, Ruhr-University Bochum, Germany

Hydrogen is essential for sustainable industries but can also cause severe degradation through hydrogen embrittlement (HE). Trapping H at microstructural defects helps mitigate HE, though its efficiency depends on how each defect affects H solution energy.

This study combines experiments and DFT calculations to examine how microstructural defects in ferritic steels influence H trapping, focusing on different grain boundary (GB) types with and without segregants.

DFT was used to calculate solution energies at several special GBs in ferrite, both clean and with alloying elements (Cr, Cu, Ti) or vacancies, and these energies were linked to structural and electronic GB parameters.

Ferritic model alloys with varied compositions were produced and characterised. By optimizing processing, we increased the fraction of special GBs in the microstructure (Şen et al., JMRT (2025)).

The calculated solution energies serve as input for Oriani's model to predict thermal desorption spectra of these alloys.

Overall, this work shows how combining simulations and experiments clarifies the role of microstructural heterogeneities in HE.

Keywords: hydrogen embrittlement; ab initio density functional theory; EBSD; TDS; grain boundary engineering