Harnessing Anti-Parity-Time Phase Transition in Coupled Topological Photonic Valley Waveguides

Topological and non-Hermitian physics provide powerful tools for manipulating light in different ways. Recently, intense studies have converged on the interplay between topology and non-Hermiticity, and have produced fruitful results in various photonic settings. Currently, the realization of this interplay falls under the paradigm of enabling energy exchange between topological systems and the environment. Beyond this paradigm, it is revealed that a non-Hermitian phenomenon, i.e., the anti-parity-time phase transition, naturally emerges from a Hermitian system realized by coupled topological valley waveguides. Such phase transition gives two exotic topological superstates in the spectral domain. By further combining the two phases with topological robustness, a photonic topological bi-functional device is realized on a silicon-on-insulator platform at telecommunications frequencies. The results provide a new perspective on light manipulation and integrated device applications.

Automated summary

Topological and non-Hermitian physics offer powerful tools for manipulating light, and recent studies on their interplay have yielded fruitful results in various photonic settings. The realization of this interplay currently focuses on enabling energy exchange between topological systems and the environment. However, it has been discovered that a non-Hermitian phenomenon called the anti-parity-time phase transition naturally emerges from a Hermitian system realized by coupled topological valley waveguides. This phase transition gives rise to two exotic topological superstates in the spectral domain and enables the realization of a photonic topological bi-functional device on a silicon-on-insulator platform at telecommunications frequencies.