Nontrivial topological flat bands in a diamond-octagon lattice geometry

TL;DR

This paper introduces a two-dimensional diamond-octagon lattice model that hosts nearly flat bands with nonzero Chern numbers, which are promising for realizing fractional topological phases and can be experimentally implemented in optical or photonic systems.

Contribution

The study demonstrates the emergence of topologically nontrivial nearly flat bands in a diamond-octagon lattice through a tight-binding model with magnetic flux and diagonal hopping, and shows how to achieve perfect flat bands.

Findings

Nearly flat bands with nonzero Chern numbers identified.

Parameter tuning leads to perfect flat bands and localized states.

Potential realization in ultracold gases and photonic lattices.

Abstract

We present the appearance of nearly flat band states with nonzero Chern numbers in a two-dimensional "diamond-octagon" lattice model comprising two kinds of elementary plaquette geometries, diamond and octagon, respectively. We show that the origin of such nontrivial topological nearly flat bands can be described by a short-ranged tight-binding Hamiltonian. By considering an additional diagonal hopping parameter in the diamond plaquettes along with an externally fine-tuned magnetic flux, it leads to the emergence of such nearly flat band states with nonzero Chern numbers for our simple lattice model. Such topologically nontrivial nearly flat bands can be very useful to realize the fractional topological phenomena in lattice models when the interaction is taken into consideration. In addition, we also show that perfect band flattening for certain energy bands, leading to compact localized states can be accomplished by fine-tuning the parameters of the Hamiltonian of the system. We compute the density of states and the wavefunction amplitude distribution at different lattice sites to corroborate the formation of such perfectly flat band states in the energy spectrum. Considering the structural homology between a diamond-octagon lattice and a kagome lattice, we strongly believe that one can experimentally realize a diamond-octagon lattice using ultracold quantum gases in an optical lattice setting. A possible application of our lattice model could be to design a photonic lattice using single-mode laser-induced photonic waveguides and study the corresponding photonic flat bands.