Thermal transport signatures of the excitonic transition and associated phonon softening in the layered chalcogenide Ta2NiSe5

Abstract

The layered compound Ta2NiSe5 is a quasi-one-dimensional and narrow-gap semiconductor, which is proposed to undergo a transition to an excitonic insulator at Tc=326 K. We found a clear anomaly at Tc in the in-plane thermal conductivities both parallel ( a) and perpendicular ( c) to the one-dimensional chains, a and c. While a shows a rapid decrease below Tc, c shows a pronounced V-shaped suppression centered at Tc. We argue that the decrease of a represents the suppression of the quasiparticle contribution below Tc due to excitonic condensation. On the other hand, the V-shaped suppression of c comes from the enhanced phonon scattering by soft phonons associated with the monoclinic transition with momentum q c. The continued suppression of c up to an extremely high temperature above Tc suggests the persistence of phonon softening likely coupled to electronic, presumably excitonic, fluctuations.