A High-Q Vertical Light Emission From Active Parity-Time Symmetric Gratings

TL;DR

This paper theoretically investigates active PT-symmetric photonic gratings, revealing bifurcation properties, spectral singularities, and near-zero bandwidth emission, which could enable advanced surface-emitting photonic devices.

Contribution

It introduces a novel analysis of free-space emission modes in active PT-symmetric gratings, highlighting spectral singularities and their relation to scattering matrix formation.

Findings

Identification of bifurcation behavior due to PT-symmetry modulation

Discovery of spectral singularities leading to near-zero bandwidth emission

Relation of SS modes to the scattering matrix formation

Abstract

This work presents a theoretical investigation of an active photonic grating of the parity-time (PT) symmetric architecture. The analytical study of the free-space mode propagation from the grating structure indicates the unique bifurcation property due to the PT-symmetry modulation. It is shown that both the gain/loss contrast and the lattice constant parameters are critical factors to modulate the active photonic system in between the PT-symmetry to the symmetry-broken phases. Furthermore, numerical simulations via the Rigorous Coupled-Wave Analysis (RCWA) method discover the existence of a unique Spectral Singularity (SS) phenomenon in this PT grating structure, which corresponds to a non-trivial single-mode and near-zero bandwidth photonic resonant emission. Also, the guiding procedure for fulfilling SS modes is found to be related to the unique formation of the scattering matrix applied in the PT-symmetric photonic gratings. This theoretical work takes a fresh look into the active PT-symmetric photonic gratings focusing on the discovery of new free-space emission modes rather than the commonly studied unidirectional properties, which could contribute to the development of novel low-threshold and super-coherent surface-emitting devices.