Exceptional Points in Hybrid-Plasmonic Quasiparticles for Ultracompact Modulators

TL;DR

This paper introduces a novel approach using exceptional points in hybrid-plasmonic quasiparticles to achieve ultracompact, high-performance electro-optical modulators with dynamic tunability and enhanced device responsivity.

Contribution

It demonstrates the use of non-Hermitian physics and exceptional points in multilayer structures with phase-change materials for dynamic, highly responsive photonic modulation.

Findings

Achieved sub-micron modulation distances with high responsivity.

Controlled coupling regimes enable tunable exceptional point degeneracies.

Integrated low-loss phase-change materials for dynamic electrical tuning.

Abstract

Current progress in electro-optical modulation within silicon integrated photonics, driven by the unique capabilities of advanced functional materials, has led to significant improvements in device performance. However, inherent constraints in dimensionality and tunability still pose challenges for further innovation. In this work, we propose a strategy that exploits the principles of non-Hermitian physics--specifically, the concept of exceptional points (EPs)--to transcend these limitations and pave the way for the next generation of versatile, high-performance photonic devices. Our multilayer structure supports hybrid plasmonic waveguide modes that can manifest as various orders of quasiparticles. By judiciously setting spatial parameters, the system can be tuned to exhibit both weak and strong coupling regimes between the plasmonic and dielectric modes, leading to the controlled formation of EP degeneracies. Furthermore, the integration of low-loss phase-change materials (Sb2S3 and Sb2Se3) enables dynamic electrical tuning, resulting in pronounced modulation of propagation loss and transmission coefficients over sub-micron distances. This superior performance not only sets a new benchmark for device responsivity and compactness but also opens promising avenues for future research, including the incorporation of gain media for loss compensation at EPs and the exploration of alternative tunable materials for next-generation ultracompact photonic devices.