What question did this study set out to answer?

The aim is to design and demonstrate side-coupled Fabry–Pérot resonators using broadband dispersion-engineered Bragg gratings.

May 20, 2026Open Access

Broadband dispersion-engineered Bragg grating mirrors for integrated side-coupled Fabry–Pérot resonators

Key Points

The aim is to design and demonstrate side-coupled Fabry–Pérot resonators using broadband dispersion-engineered Bragg gratings.
Designed silicon nitride side-coupled Fabry–Pérot resonators with uniform and apodised distributed Bragg reflectors.
Implemented air-gap Bragg gratings achieving a stopband exceeding 70 nm.
Co-optimised cavity length and waveguide-to-cavity gap for enhanced performance.
Achieved a broad stopband exceeding 70 nm.
Demonstrated high-Q resonant modes and enhanced peak reflectivity.
Showed improved spectral bandwidth control and mode selectivity.

Abstract

Abstract We present the design and demonstration of silicon nitride side-coupled Fabry–Pérot resonators employing both uniform and apodised distributed Bragg reflectors, for broadband dispersion engineering. By implementing air-gap Bragg gratings, we achieve a broad stopband exceeding 70 nm. Apodised gratings enable enhanced dispersion control, allowing transitions from normal to anomalous integrated dispersion. Furthermore, high-Q resonant modes and enhanced peak reflectivity are demonstrated through co-optimisation of cavity length and waveguide-to-cavity gap. The compact footprint, the enhanced mode selectivity and the spectral bandwidth control, make side-coupled Fabry-Pérot resonators a promising platform for resonant mirrors in hybrid on-chip lasers, as well as for sensing and non-linear photonic systems.

Bookmark

View Full Paper

Bookmark

View Full Paper

Broadband dispersion-engineered Bragg grating mirrors for integrated side-coupled Fabry–Pérot resonators

Key Points

Abstract

Cite This Study