Planar Waveguide Circulating Gaussian Beam Resonators on a Silicon Photonic Chip

TL;DR

This paper introduces a silicon photonic waveguide resonator with a circulating Gaussian mode, demonstrating high-Q resonances and broadband operation, suitable for integrated photonic applications.

Contribution

It presents a novel planar waveguide resonator design with a circulating Gaussian mode, featuring wavelength-independent, lossless coupling and high Q-factors, advancing integrated photonic resonator technology.

Findings

Achieved resonance line widths of 5 pm with Q=310000.

Demonstrated broadband operation over 100 nm tuning range.

Resonator shows reduced sensitivity to fabrication imperfections.

Abstract

A Si slab waveguide resonator design with a circulating Gaussian-like cavity mode is described and characterized, for both all-pass and add-drop configurations and several different input/output coupling strengths. The circulating beam propagates in a slab waveguide with no lateral confinement. Three straight mirrors and one curved mirror define a folded two-dimensional Gaussian cavity. Light is coupled to and from the resonator by beam splitters formed by a narrow gap between a cavity mirror and the input slab waveguides. The coupling is determined by the gap width and is wavelength independent and lossless. For a L=100 um path length cavity, resonance line widths of 5 pm with Q-values of Q = 310000 were measured. The resonator drop spectrum exhibited a comb of almost identical resonance lines across a 100 nm tuning range. This resonator design is capable of broadband operation and is less susceptible to sidewall roughness and defect scattering induced loss and mode splitting, when compared with Si rings formed from narrow single mode waveguides.