FFLO Excitonic State in the Three-Chain Hubbard Model for Ta2NiSe5

Abstract

The three-chain Hubbard model for Ta2NiSe5 known as a candidate material for the excitonic insulator is investigated over the wide range of energy gap D between the two-fold degenerate conduction bands and the nondegenerate valence band including both semiconducting (D>0) and semimetallic (D<0) cases. In the semimetallic case, the difference of the band degeneracy inevitably causes the imbalance of each Fermi wavenumber, resulting in a remarkable excitonic state characterized by the condensation of excitons with finite center-of-mass momentum q, the so-called Fulde-Ferrell-Larkin-Ovchinnikov (FFLO) excitonic state. With decreasing D corresponding to increasing pressure, the obtained excitonic phase diagram shows a crossover from BEC (D 0) to BCS (D 0) regime, and then shows a distinct phase transition at a certain critical value Dc(<0) from the uniform (q=0) to the FFLO (q 0) excitonic state, as expected to be observed in Ta2NiSe5 under high pressure.