Edge States and Topological Phases in One-Dimensional Optical Superlattices

AbstractWe theoretically report the finding of a new kind of topological phase transition between a normal insulator and a topological metal state where the closing-reopening of bandgap is accompanied by passing the Fermi level through an additional band. The resulting nontrivial topological metal phase is characterized by stable zero-energy localized edge states that exist within the full gapless bulk states. Such states living on a quasi-one-dimensional system with three sublattices per unit cell are protected by hidden inversion symmetry. While other required symmetries such as chiral, particle-hole, or full inversion symmetry are absent in the system.

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Topological gaps by twisting

Communications Physics ◽

10.1038/s42005-021-00630-3 ◽

2021 ◽

Vol 4 (1) ◽

Author(s):

Matheus I. N. Rosa ◽

Massimo Ruzzene ◽

Emil Prodan

Keyword(s):

Magnetic Field ◽

Quantum Hall Effect ◽

Twist Angle ◽

Quantum Hall ◽

Topological Phases ◽

Edge States ◽

Layered Systems ◽

Virtual Laboratories ◽

Higher Dimensional ◽

Chern Numbers

AbstractTwisted bilayered systems such as bilayered graphene exhibit remarkable properties such as superconductivity at magic angles and topological insulating phases. For generic twist angles, the bilayers are truly quasiperiodic, a fact that is often overlooked and that has consequences which are largely unexplored. Herein, we uncover that twisted n-layers host intrinsic higher dimensional topological phases, and that those characterized by second Chern numbers can be found in twisted bi-layers. We employ phononic lattices with interactions modulated by a second twisted lattice and reveal Hofstadter-like spectral butterflies in terms of the twist angle, which acts as a pseudo magnetic field. The phason provided by the sliding of the layers lives on 2n-tori and can be used to access and manipulate the edge states. Our work demonstrates how multi-layered systems are virtual laboratories for studying the physics of higher dimensional quantum Hall effect, and can be employed to engineer topological pumps via simple twisting and sliding.

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Non-Hermitian route to higher-order topology in an acoustic crystal

Nature Communications ◽

10.1038/s41467-021-22223-y ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

He Gao ◽

Haoran Xue ◽

Zhongming Gu ◽

Tuo Liu ◽

Jie Zhu ◽

...

Keyword(s):

Higher Order ◽

Order Topology ◽

Topological Phases ◽

Edge States ◽

Experimental Realization ◽

Artificial Materials ◽

Intrinsic Loss ◽

Topological Phases Of Matter ◽

Hierarchical Features ◽

Nontrivial Topology

AbstractTopological phases of matter are classified based on their Hermitian Hamiltonians, whose real-valued dispersions together with orthogonal eigenstates form nontrivial topology. In the recently discovered higher-order topological insulators (TIs), the bulk topology can even exhibit hierarchical features, leading to topological corner states, as demonstrated in many photonic and acoustic artificial materials. Naturally, the intrinsic loss in these artificial materials has been omitted in the topology definition, due to its non-Hermitian nature; in practice, the presence of loss is generally considered harmful to the topological corner states. Here, we report the experimental realization of a higher-order TI in an acoustic crystal, whose nontrivial topology is induced by deliberately introduced losses. With local acoustic measurements, we identify a topological bulk bandgap that is populated with gapped edge states and in-gap corner states, as the hallmark signatures of hierarchical higher-order topology. Our work establishes the non-Hermitian route to higher-order topology, and paves the way to exploring various exotic non-Hermiticity-induced topological phases.

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