Pressure induced electronic structure transformation of topological semimetal

Abstract

We study the electronic structure change of yttrium trihydride YH3 by applying a hydrostatic pressure. At zero pressure, YH3 has the structure with energy favored symmetry group P3c1 (165). From first principle calculation, we argue that the band crossings are caused by overlapping of an electron- and hole-like bands. Besides the space inversion symmetry (I) and the time reversal symmetry, the band structure also exhibits an approximate particle-hole symmetry. Thus, YH3 can be viewed as a pseudo nodal surface semimetal belongs to class BDI of the ten-fold AZ+ I classifications of gapless topological matter. As pressure increases, the approximate particle-hole symmetry is gradually broken and the pseudo nodal surface turns into a nodal ring belonging to the class AI with fewer non-spatial symmetries. Also, the nodal ring is shrinking in the process. At about 31 GPa, which is higher than the reported structure phase transition pressure 21 GPa, the nodal ring shrinks to a nodal point. When above 31 GPa, all band crossings are gapped out and YH3 becomes a trivial insulator eventually.