Backscattering-Immune Floquet Conversion in Ring Modulators

TL;DR

This paper presents a novel method to eliminate backscattering in micro-ring cavities by operating at an exceptional point, enhancing Floquet mode conversion efficiency and enabling better integration in photonic systems.

Contribution

The work introduces a non-conservative coupling approach at an exceptional point to suppress backscattering, improving device performance without complex fabrication.

Findings

Backscattering is effectively suppressed at the exceptional point.

Significant enhancement in Floquet mode conversion efficiency.

Method is adaptable for integration into various photonic platforms.

Abstract

Backscattering in micro-ring cavities induces mode mixing and limits device performance. Existing methods to mitigate backscattering often involve complex fabrication processes or are insufficient for complete suppression. In this work, we introduce a novel method to eliminate backscattering by operating the cavity at an exceptional point (EP). By engineering non-conservative coupling between degenerate clockwise (CW) and counter-clockwise (CCW) modes, we achieve chiral transmission that prevents degeneracy lifting and suppresses unwanted mode coupling. Unlike previous approaches that rely on precise gain-loss balance or complex structures, our method utilizes non-conservative coupling between the counterpropgating cavity modes. Using this method, we further show significant enhancement in the cavity performance in Floquet mode conversion efficiency at the EP. Our highly adaptable approach enables seamless integration into various photonic platforms with electro-optic modulators. This advancement mitigates backscattering and improves the precision of light-matter interactions, offering promising applications in quantum communication and information processing.