Grain boundary segregation in BCC vanadium-based alloys: Quantum- accurate computed segregation spectra and targeted experimental validations

M Wagih and TJ Lei and D Ng and CA Schuh, ACTA MATERIALIA, 294, 121169 (2025).

DOI: 10.1016/j.actamat.2025.121169

Grain boundaries are critically important to the material performance of fusion reactor materials such as vanadium, particularly mechanical properties and irradiation resistance. A key challenge to the design and control of grain boundaries in vanadium alloys is the lack of quantitative data on grain boundary segregation. In this study, we combine computational and experimental methods to address this gap. Using a machine learningaccelerated quantum mechanics/molecular mechanics approach, we calculated the segregation spectra for 28 transition metal elements in polycrystalline vanadium, and validated these predictions experimentally for a subset of solutes that sample a range of segregation behavior, specifically zirconium, titanium, and tungsten, using analytical transmission electron microscopy. The agreement between experiment and theory highlights the predictive capability of our approach. Critically, this work provides a comprehensive database of quantumaccurate solute segregation enthalpies in vanadium, enabling the development of advanced alloys for fusion reactors applications.

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