Nonlinear optics at low powers: new mechanism of on-chip optical frequency comb generation

TL;DR

This paper introduces a novel low-power mechanism for on-chip optical frequency comb generation using period-doubling bifurcations near nonlinear cavity anti-resonance, overcoming limitations of high-power nonlinear effects.

Contribution

It proposes a new approach leveraging nonlinear cavity anti-resonance for efficient low-power optical comb generation, contrasting with traditional high-power methods.

Findings

Demonstrates strong nonlinear effects at low intensities

Achieves optical comb generation on a silicon chip at low power

Provides an alternative to high-Q resonator-based nonlinear enhancement

Abstract

Nonlinear optical effects provide a natural way of light manipulation and interaction, and form the foundation of applied photonics -- from high-speed signal processing and telecommunication, to ultra-high bandwidth interconnects and information processing. However, relatively weak nonlinear response at optical frequencies calls for operation at high optical powers, or boosting efficiency of nonlinear parametric processes by enhancing local field intensity with high quality-factor resonators near cavity resonance, resulting in reduced operational bandwidth and increased loss due to multi-photon absorption. We present an alternative to this conventional approach, with strong nonlinear optical effects at low local intensities, based on period-doubling bifurcations near nonlinear cavity anti-resonance, and apply it to low-power optical comb generation in a silicon chip.