Phase diagram of Hubbard-Holstein model on 4-leg tube system at quarter-filling

Abstract

We derive an effective electronic Hamiltonian for square lattice Hubbard-Holstein model (HHM) in the strong electron-electron (e-e) and electron-phonon (e-ph) coupling regime and under non-adiabatic conditions (t/ω0 ≤ 1), t and ω0 being the electron hopping and phonon frequency respectively. Using Density Matrix Renormalization Group method, we simulate this effective electronic model on 4-Leg cylinder system at quarter-filling and present a phase diagram in g-U plane where g and U are being the e-ph coupling constant and Hubbard on-site interaction respectively. For larger g, we find cluster of spins i.e. phase separation (PS) gives way to a charge density wave (CDW) phase made of NN singlets which abruptly goes to another CDW phase as we increase U. But for smaller g, we find a metallic phase sandwiched between PS and singlet CDW phase. This phase is characterized by vanishing charge gap but finite spin gap -- suggesting a singlet superconducting phase.