Generalized Parametric Space, Parity Symmetry of Reflection, and Systematic Design Approach for Parity-Time Symmetric Photonic Systems

TL;DR

This paper introduces a generalized parametric space for PT symmetric photonic systems, enabling comprehensive analysis and design of exotic PT phenomena and devices through an analytical framework based on the transfer matrix and reciprocity theorem.

Contribution

It develops a systematic approach using a generalized parametric space to analyze and design PT symmetric photonic systems with novel functionalities.

Findings

Demonstrated PT heterostructure with perfect absorption-lasing

Derived complex dielectric permittivities for subwavelength PT systems

Achieved various exotic PT functionalities through analytical formulas

Abstract

Based on the reciprocity theorem, we put forward a generalized parametric space for an arbitrary transfer matrix with parity time (PT) symmetry. Through this space, one can extract complete information involving PT phases, reflectances, transmittance and known extraordinary scattering phenomena. We demonstrate a PT heterostructure with coherent perfect absorption-lasing, anisotropic transmission resonance, and parity symmetry of reflection coefficients at the frequencies of interest. In addition, with the parametric space and the analytical formula, the corresponding complex dielectric permittivities for a simple PT system made of a gain, a gap, and a loss media in deeply subwavelength is derived to achieve various exotic PT functionality. This work could offer an alternative route to design versatile optical and photonic PT devices.