Trigonal-to-monoclinic structural transition in TiSe2 due to a combined condensation of q = (12,0,0) and (12,0,12) phonon instabilities

Abstract

I present first principles calculations of the phonon dispersions of TiSe2 in the P3c1 phase, which is the currently accepted low-temperature structure of this material. They show weak instabilities in the acoustic branches in the out-of-plane direction, suggesting that this phase may not be the true ground state. To find the lowest energy structure, I study the energetics of all possible distorted structures corresponding to the isotropy subgroups of P3m1 for the M1- and L1- phonon instabilities present in this high-temperature phase at q = (12,0,0) and (12,0,12), respectively. I was able to stabilize 10 different structures that are lower in energy relative to the parent P3m1 phase, including two monoclinic structures more energetically stable than the P3c1 phase. The lowest energy structure has the space group C2 with the order parameter M1- (a,0,0) + L1- (0,b,b). This structure lacks inversion symmetry, and its primitive unit cell has 12 atoms.