Realization of topological superlattices and the associated interface states in one-dimensional plasmonic crystals

TL;DR

This paper explores the creation and control of multiple topologically protected interface states in one-dimensional plasmonic superlattices, revealing new states with potential for robust signal transmission.

Contribution

It demonstrates the design of 1D metallic superlattices supporting multiple interface states and shows how their band topology can be tuned by structural configurations.

Findings

Single interface states exist at boundaries of topologically distinct arrays.

New superlattice interface states form when trivial and nontrivial superlattices are combined.

Superlattice interface states have smaller divergence and longer localization, suitable for robust transmission.

Abstract

In analogous to the Su-Schrieffer-Heeger (SSH) model, one-dimensional (1D) electromagnetic (EM) crystals can exhibit nontrivial topological properties. In particular, when a nontrivial EM crystal is in contact with its trivial counterpart, a topologically protected interface state is formed. While much attention has been focused on single interface state, multiple interface states can interact collectively when under suitable conditions, giving rise to trivial or nontrivial band topologies resembling to the standard SSH model. Here, we study the topological properties of 1D metallic superlattices that support multiple interface states. We first demonstrate single interface state exists at the boundary between two topologically distinct metallic arrays that carry Bloch-like surface plasmon polaritons. Such interface state is then used as the building block for further constructing the superlattices. By exploiting the separation between two dimerized interface states and the distinct inter- and intra-interface configurations to facilitate different intracell and intercell interactions, we vary the band topology of the superlattices. More importantly, new superlattice interface state is formed when trivial and nontrivial superlattices are brought together. The superlattice interface state is found to have smaller angular divergence and longer localization length than its single counterpart, thus is desired for robust signal transmission and high finesse cavity.