Holstein polaron in a pseudospin-$1$ quantum spin Hall system: first and second order topological phase transitions

TL;DR

This paper predicts and analyzes topological phase transitions in a pseudospin-1 fermionic system on an $ ext{alpha}$-$T_3$ lattice driven by electron-phonon coupling, including the emergence of second order topological phases with corner modes.

Contribution

It introduces a theoretical model combining Kane-Mele and Holstein Hamiltonians to study electron-phonon effects on topological phases in a pseudospin-1 system, revealing new higher order topological transitions.

Findings

Topological phases exist up to a critical electron-phonon coupling $ ext{lambda}_c$.

Higher order topological phases with corner modes are induced by magnetic fields.

Electron-phonon coupling significantly affects the stability of topological and corner states.

Abstract

We theoretically propose the occurrence of a quantum spin Hall (QSH) and a second order topological phase transition (TPT) driven by electron-phonon (e-p) coupling in a pseudospin-$1$ fermionic system on an $\alpha$-$T_3$ lattice. Our model is formulated in the spirit of the Kane-Mele model modified by the Holstein Hamiltonian. The Lang-Firsov approach is employed to describe polarons reasonably well in the anti-adiabatic (high frequency) limit and to obtain an effective electronic Hamiltonian. It is shown that the system possesses topologically nontrivial phases up to a critical e-p coupling, $\lambda_c$ and are characterized by the helical QSH edge states along with a non-zero $\mathbb{Z}_2$ invariant for a certain range of $\alpha$. The topological phase vanishes beyond $\lambda_c$ and is accompanied by a bulk gap closing transition at $\lambda_c$, manifesting a TPT. We observe a more intriguing phenomenon for higher values of $\alpha$, where the system exhibits TPTs supported by two distinct gap closing transitions at $\lambda_{c_1}$ and $\lambda_{c_2}$, while a slim region at slightly lower values hosts a semi-metallic signature below $\lambda_{c_1}$. Subsequently, to explore more intricate features, we introduce a time reversal symmetry breaking magnetic field to trigger the formation of a second order topological phase. The magnetic field, by construction causes a boundary dependent gapping out of the edge states, consequently giving rise to robust corner modes in a tailored open boundary conditions. We justify the formation of the higher order phase by employing an appropriate invariant, namely the projected spin Chern number. Finally, we show that the e-p coupling significantly influences the corner modes (and also the real space energy bandstructure), corroborating a higher order TPT as we tune $\lambda$ beyond a critical value for a given value of $\alpha$.