First-principles insights into metallic doping effects on yttrium twin grain boundary

Abstract

This study systematically investigates the effects of 34 metallic dopants on the {$10\overline{1}0$} grain boundary in Yttrium-based alloys using first-principles calculations. Results reveal a strong segregation tendency of dopants near the grain boundary due to favorable segregation energies, with energy barriers influencing segregation positions. Strengthening energy calculations show all dopants enhance grain boundary strength when located nearby. Considering the stability of the grain boundary, 11 elements (Al, Zn, etc) are identified as preferentially segregating near the grain boundary, contributing to enhanced strength and stability. Trends in grain boundary energy and solubility among transition group elements correlate with valence electrons. Decomposition of strengthening energy reveals that chemical contributions dominate, while mechanical effects correlate with changes in Voronoi volume and solute atomic radius. DOS analysis indicates that hybridization between solutes and Yttrium d orbitals stabilizes the grain boundary. This study provides theoretical insights for optimizing dopants in Y-based alloys.