Lattice fluctuations, not excitonic correlations, mediated electronic localization in TiSe2

Abstract

TiSe2 is thought to be an insulator with a bandgap of ~0.1eV. It has attracted a much interest because, among of a rich array of unique properties, many have thought TiSe2 is a rare realisation of an excitonic insulator. Below 200 K, TiSe2 undergoes a transition from a high-symmetry (P-3m1) phase to a low-symmetry (P-3c1) phase. Here we establish that TiSe2 is indeed an insulator in both P-3m1 and P-3c1 phases. However, the insulating state is driven not by excitonic effects but by symmetry-breaking of the P-3m1 phase. In the CDW phase the symmetry breaking is static. At high temperature, thermally driven instantaneous deviations from P-3m1 break the symmetry on the characteristic time scale of a phonon. Even while the time-averaged lattice structure assumes P-3m1 symmetry, the time-averaged energy band structure is closer to the CDW phase -- a rare instance of a metal-insulator transition induced by dynamical symmetry breaking. We establish these conclusions from a high-fidelity, self-consistent form of many body perturbation theory, in combination with molecular dynamics simulations to capture the effects of thermal disorder. The many-body theory includes explicitly ladder diagrams in the polarizability, which incorporates excitonic effects in an ab initio manner. The excitonic modification to the potential is slight, ruling out the possibility that TiSe2 is an excitonic insulator. Charge self-consistency is essential distinguish the metallic from insulating state.

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