Unidirectional Amplification in the Frozen Mode Regime Enabled by a Nonlinear Defect

TL;DR

This paper introduces a novel unidirectional amplifier leveraging a nonlinear defect in a periodic structure at the stationary inflection point, enabling efficient, non-resonant light amplification with robustness to impurities.

Contribution

It proposes a new scheme for unidirectional amplification using a nonlinear defect near the SIP, breaking symmetry and enabling nonlinearity-based control.

Findings

Effective unidirectional amplification demonstrated near SIP frequency.

Robustness of the amplification mechanism to impurities and parasitic effects.

Non-resonant frozen mode regime offers advantages over cavity resonances.

Abstract

A stationary inflection point (SIP) is a spectral singularity of the Bloch dispersion relation $\omega(k)$ of a periodic structure where the first and the second derivatives of $\omega$ with respect to $k$ vanish. An SIP is associated with a third order exceptional point degeneracy in the spectrum of the unit-cell transfer matrix, where there is a collapse of one propagating and two evanescent Bloch modes. At the SIP frequency, the incident wave can be efficiently converted into the frozen mode with greatly enhanced amplitude and vanishing group velocity. This can be very attractive for applications, including light amplification. Due to its non-resonant nature, the frozen mode regime (FMR) has fundamental advantages over common cavity resonances. Here, we propose a novel scheme for FMR-based unidirectional amplifiers by leveraging a tailored amplification/attenuation mechanism and a single nonlinear defect. The defect breaks the directional symmetry of the periodic structure and enables nonlinearity-related unidirectional amplification/ attenuation in the vicinity of the SIP frequency. We demonstrate the robustness of the amplification mechanism to local impurities and parasitic nonlinearity.