Excitonic Instability in Ta2Pd3Te5 monolayer

By systematic theoretical calculations, we have revealed an excitonic insulator (EI) in a van der Waals (vdW) layered compound Ta2Pd3Te5. The interlayer binding energy in the vdW layered compound is 19.6 meV/x212B^2. The computed phonon spectrum suggests that the monolayer is dynamically stable without lattice distortion. The monolayer can be obtained by exfoliation or molecular-beam epitaxy. First-principles calculations show that the monolayer is a nearly zero-gap semiconductor with the modified Becke-Johnson functional. Due to the like symmetry of the band-edge states, the 2D polarization α_2D would be finite as the band gap goes to zero, allowing for the EI state in the compound. Using the first-principles many-body perturbation theory, the GW-BSE calculation reveals that the exciton binding energy E_b is larger than the single-particle band gap E_g, indicating the excitonic instability. Our findings suggest that the Ta2Pd3Te5 monolayer is an excitonic insulator without structural distortion.