Elastocaloric signature of the excitonic instability in Ta2NiSe5

Abstract

On cooling through a temperature TS of around 324 K, Ta2NiSe5 undergoes a transition from a semimetallic state to one with a gapped electronic spectrum which is suspected to be an excitonic insulator. However, at this transition the structure also changes, from orthorhombic to monoclinic, leaving open the question of whether it is driven primarily by excitonic ordering or by a lattice instability. A lattice instability of this symmetry would correspond to softening of a B2g optical or acoustic phonon mode. Here, we report that elastocaloric measurements of Ta2NiSe5 with induced B2g strain reveal a thermodynamic susceptibility described by a Curie-Weiss law with a Curie temperature T* of 298 K. The fact that T* is close to TS rules out the possibility that the B2g acoustic mode is responsible for the transition. Since prior Raman measurements have shown minimal softening of the B2g optical mode as well, our finding strengthens the case that the transition is largely excitonic in nature. Our work underscores the potential of using strain as a tool for separating electronic and lattice contributions in phase transitions.

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