Kerr optical parametric oscillation in a photonic crystal microring for accessing the infrared

TL;DR

This paper demonstrates a silicon nitride photonic crystal microring that enables mid-infrared optical parametric oscillation, overcoming fabrication sensitivity and nonlinear process competition issues in integrated photonics.

Contribution

It introduces a novel PhCR design that facilitates infrared OPO by leveraging bandgap-induced frequency shifts, expanding the capabilities of integrated silicon photonics.

Findings

Achieved high optical quality factor of 1.2×10^6 in the 2 μm band.

Demonstrated OPO with 90 mW threshold power at 1998 nm pump wavelength.

Generated signal and idler wavelengths at 1937 nm and 2063 nm.

Abstract

Continuous wave optical parametric oscillation (OPO) provides a flexible approach for accessing mid-infrared wavelengths between 2 $\mu$m to 5 $\mu$m, but has not yet been integrated into silicon nanophotonics. Typically, Kerr OPO uses a single transverse mode family for pump, signal, and idler modes, and relies on a delicate balance to achieve normal (but close-to-zero) dispersion near the pump and the requisite higher-order dispersion needed for phase- and frequency-matching. Within integrated photonics platforms, this approach results in two major problems. First, the dispersion is very sensitive to geometry, so that small fabrication errors can have a large impact. Second, the device is susceptible to competing nonlinear processes near the pump. In this letter, we propose a flexible solution to infrared OPO that addresses these two problems, by using a silicon nitride photonic crystal microring (PhCR). The frequency shifts created by the PhCR bandgap enable OPO that would otherwise be forbidden. We report an intrinsic optical quality factor up to (1.2 $\pm$ 0.1)$\times$10$^6$ in the 2 $\mu$m band, and use a PhCR ring to demonstrate an OPO with threshold power of (90 $\pm$ 20) mW dropped into the cavity, with the pump wavelength at 1998~nm, and the signal and idler wavelengths at 1937 nm and 2063 nm, respectively. We further discuss how to extend OPO spectral coverage in the mid-infrared. These results establish the PhCR OPO as a promising route for integrated laser sources in the infrared.