Prediction of fundamental properties of Be-B-Ta based novel ternary compounds from first-principles calculations

Abstract

Be-B/B-Ta based compounds are very attractive to researchers because of their high density and ultra-hardness. But ternary Be-B-Ta compounds are neither synthesized nor predicted. In this paper, variable composition evolutionary crystal structure prediction calculations based on first-principles method have been performed to find the stable crystal structure containing Be-B-Ta at ambient condition. The predicted five compounds BeB2Ta, BeB3Ta2 (high-pressure phase), BeBTa, BeBTa2, and Be2B2Ta have been found to be highly dense and very hard materials. All these compounds are metallic and spin-orbit coupling (SOC) effect is significant in them. Only two of them (BeB2Ta and Be2B2Ta) have been found to be superconductors within Migdal-Eliashberg theory. The calculated critical temperature including SOC effect is 8 and 9 K for BeB2Ta and Be2B2Ta, respectively. Because of their energetic and dynamic stability, these compounds might be favorable to synthesize in the laboratory.