Single-mode Dispersion-engineered Nonlinear Integrated Waveguides for Ultra-broadband Optical Amplification and Wavelength Conversion

TL;DR

This paper introduces a novel waveguide design that achieves single-mode operation and ultra-broadband four-wave mixing in integrated photonic platforms, enabling efficient optical amplification and wavelength conversion over hundreds of nanometers.

Contribution

It presents a new methodology combining waveguide cross section and bend effects to ensure single-mode dispersion engineering for broadband nonlinear optical applications.

Findings

Achieved approximately 300 nm amplification bandwidth in silicon nitride waveguides.

Demonstrated penalty-free 100 Gbit/s wavelength conversion over 200 nm.

Enabled super-broadband four-wave mixing in a compact integrated platform.

Abstract

Four-wave mixing has extensively been investigated for various applications such as communications, spectroscopy, metrology, quantum computing and bio-imaging. However, there is a clear desire to implement these functionalities in a small footprint nonlinear platform, being capable of efficient operation across a large optical bandwidth. Many such integrated platforms have been explored, but suffer from intrinsic significant performance degradation, because conventional approaches of nonlinear photonic waveguide geometry construction for dispersion engineering focus on waveguide cross section and result in always being multimode as a byproduct. Here we propose and demonstrate a methodology that utilizes not only the impact of the waveguide cross section on the modal and dispersion behavior of the waveguide but also includes the impact of the waveguide bend for cutting off high-order modes. This approach results in simultaneous single-mode operation and dispersion engineering for very broadband operation of four-wave mixing. While we implemented this in silicon nitride waveguides, which has emerged as a promising platform capable of continuous-wave optical parametric amplification, the design approach can be universally used with other platforms as well. By also considering both second- and fourth-order dispersion we achieve unprecedented amplification bandwidths of approximately 300 nm in super-low-loss silicon nitride nonlinear waveguides. In addition, penalty-free all-optical wavelength conversion of 100 Gbit/s data in a single optical carrier over 200 nm is realized, for the first time, without optical amplification of signal or idler waves. These single-mode hyper-dispersion-engineered nonlinear integrated waveguides can become practical building blocks in versatile nonlinear photonic devices and optical networks.