Band-engineered bilayer Haldane model: Evidence of multiple topological phase transitions

We have studied the evolution of the topological properties of a band-engineered, AB-stacked bilayer honeycomb structure in the presence of a Haldane flux. Without a Haldane flux, band engineering makes the band touching points (the so-called Dirac points) move towards each other and eventually merge into one at an intermediate M point in the Brillouin zone. Here the dispersion is linear along one direction and quadratic along the other. In the presence of a Haldane flux, the system acquires topological properties, and finite Chern numbers can be associated with the pairs of the conduction and the valence bands. The valence band closer to the Fermi level (EF) possesses Chern numbers equal to ±2 and ±1, while the one further away from EF corresponds to Chern numbers ±1. The conduction bands are associated with similar properties, except their signs are reversed. The Chern lobes shrink in the band-engineered model, and we find evidence of multiple topological phase transitions, where the Chern numbers discontinuously jump from ±2 to ∓2, ±1 to ∓1, ±1 to 0 to ±2, and ±2 to ±1. These transitions are supported by the presence or absence of the chiral edge modes in a nanoribbon bilayer geometry and the vanishing of the plateau in the anomalous Hall conductivity. Different phases are further computed for different hopping amplitudes across the layers, which shows shrinking of the Chern lobes for large interlayer tunneling. © 2023 American Physical Society.