Nonlinear photonic disclination states

TL;DR

This paper demonstrates the existence and properties of nonlinear photonic disclination states in higher-order topological insulators, showing how nonlinearity influences their stability, shape, and potential applications in topological photonic devices.

Contribution

It presents the first example of nonlinear photonic disclination states bifurcating from linear states in disclination lattices with pentagonal or heptagonal cores, highlighting the role of nonlinearity and lattice structure.

Findings

Nonlinear disclination states can be tuned within the bandgap.

States are stable in heptagonal lattices but unstable in pentagonal ones.

Disclination states are thresholdless and can be excited at low powers.

Abstract

Higher-order topological insulators are unusual materials that can support topologically protected states, whose dimensionality is lower than the dimensionality of the structure at least by 2. Among the most intriguing examples of such states are zero-dimensional corner modes existing in two-dimensional higher-order insulators. In contrast to corner states, recently discovered disclination states also belong to the class of higher-order topological states, but are bound to the boundary of the disclination defect of the higher-order topological insulator and can be predicted using the bulk-disclination correspondence principle. Here, we present the first example of the nonlinear photonic disclination state bifurcating from its linear counterpart in the disclination lattice with a pentagonal or heptagonal core. We show that nonlinearity allows to tune location of the disclination states in the bandgap and notably affects their shapes. The structure of the disclination lattice is crucial for stability of these nonlinear topological states: for example, disclination states are stable in the heptagonal lattice and are unstable nearly in the entire gap of the pentagonal lattice. Nonlinear disclination states reported here are thresholdless and can be excited even at low powers. Nonlinear zero-energy states coexisting in these structures with disclination states are also studied. Our results suggest that disclination lattices can be used in the design of various nonlinear topological functional devices, while disclination states supported by them may play an important role in applications, where strong field confinement together with topological protection are important, such as the design of topological lasers and enhancement of generation of high harmonics.