We study the role of the edges in determining the features of the topological phase in a quasicrystalline higher-order topological insulator. We consider a specific model consisting of two stacked Haldane models with opposite Chern number and a 30 degrees twist, whose structure is crystallographically equivalent to that of the graphene quasicrystal. We find that the gap-opening in the low-energy spectrum of the higher-order topological insulator occurs at different energies when different kinds of edges are considered. Crucially, bearded bonds appear to be necessary for the gap to appear close to the charge neutrality point. In the more realistic case of zigzag edges, the gap opens symmetrically in the electron and hole sectors, away from zero energy. We explain our findings by inspecting the edge bands of the decoupled bilayer, in the approximation of quasiperiodicity.
Role of the edges in a quasicrystalline Haldane model
Traverso, S;Sassetti, M;Traverso Ziani N
2022-01-01
Abstract
We study the role of the edges in determining the features of the topological phase in a quasicrystalline higher-order topological insulator. We consider a specific model consisting of two stacked Haldane models with opposite Chern number and a 30 degrees twist, whose structure is crystallographically equivalent to that of the graphene quasicrystal. We find that the gap-opening in the low-energy spectrum of the higher-order topological insulator occurs at different energies when different kinds of edges are considered. Crucially, bearded bonds appear to be necessary for the gap to appear close to the charge neutrality point. In the more realistic case of zigzag edges, the gap opens symmetrically in the electron and hole sectors, away from zero energy. We explain our findings by inspecting the edge bands of the decoupled bilayer, in the approximation of quasiperiodicity.
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