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Critical charge fluctuations and emergent coherence in a strongly correlated excitonic insulator

P. A. Volkov, Mai Ye, H. Lohani, I. Feldman, A. Kanigel, G. Blumberg

2021npj Quantum Materials41 citationsDOIOpen Access PDF

Abstract

Abstract Excitonic insulator is a coherent electronic phase that results from the formation of a macroscopic population of bound particle-hole pairs—excitons. With only a few candidate materials known, the collective excitonic behavior is challenging to observe, being obscured by crystalline lattice effects. Here we use polarization-resolved Raman spectroscopy to reveal the quadrupolar excitonic mode in the candidate zero-gap semiconductor Ta 2 NiSe 5 disentangling it from the lattice phonons. The excitonic mode pronouncedly softens close to the phase transition, showing its electronic character, while its coupling to noncritical lattice modes is shown to enhance the transition temperature. On cooling, we observe the gradual emergence of coherent superpositions of band states at the correlated insulator gap edge, with strong departures from mean-field theory predictions. Our results demonstrate the realization of a strongly correlated excitonic state in an equilibrium bulk material.

Topics & Concepts

Condensed matter physicsPhysicsLattice (music)Insulator (electricity)Coherence (philosophical gambling strategy)PhononExcitonSemiconductorMetal–insulator transitionRaman spectroscopyPhase transitionPopulationBand gapBound stateCoupling strengthElectronic structureRaman scatteringSpectroscopyCoupling (piping)Optical latticeExcitationAmplitudeElectronic band structureTopological insulatorStrongly correlated materialCharge density wave2D Materials and ApplicationsSemiconductor Quantum Structures and DevicesStrong Light-Matter Interactions
Critical charge fluctuations and emergent coherence in a strongly correlated excitonic insulator | Litcius