New-generation silicon photonics beyond the singlemode regime

TL;DR

This paper introduces a new silicon photonics approach beyond the singlemode regime, achieving ultra-low-loss, high-Q resonators, and high-performance microwave photonic filters with broad applications in large-scale integration.

Contribution

It proposes a novel multimode silicon photonic waveguide design with broadened cores, enabling low-loss, high-Q resonators and advanced photonic devices without complex fabrication.

Findings

Achieved ~0.1 dB/cm loss for fundamental mode in broadened core waveguides

Recorded intrinsic Q-factor of 1.02×10^7 in micro-racetrack resonators

Demonstrated a microwave photonic filter with 20.6 MHz bandwidth and 20 GHz tuning range

Abstract

The singlemode condition is one of the most important design rules for optical waveguides in guided-wave optics. The reason following the singlemode condition is that higher-order modes might be excited and thus introduce some undesired mode-mismatching loss as well as inter-mode crosstalk when light propagates along an optical waveguide beyond the singlemode regime. As a result, multimode photonic waveguides are usually not allowed. In this paper, we propose the concept of silicon photonics beyond the singlemode regime, developed with low-loss and low-crosstalk light propagation in multimode photonic waveguides with broadened silicon cores. In particular, silicon photonic waveguides with a broadened core region have shown an ultra-low-loss of ~0.1 dB/cm for the fundamental mode even without any special fabrication process. A micro-racetrack resonator fabricated with standard 220-nm-SOI MPW-foundry processes shows a record intrinsic Q-factor as high as 1.02*107 for the first time, corresponding to ultra-low waveguide propagation loss of only 0.065 dB/cm. A high-performance microwave photonic filter on silicon is then realized with an ultra-narrow 3-dB bandwidth of 20.6 MHz as well as a tuning range of ~20 GHz for the first time. An on-chip 100-cm-long delayline is also demonstrated by using the present broadened SOI photonic waveguides with compact Euler-curve bends, the measured propagation loss is ~0.14 dB/cm. The proposed concept of silicon photonics beyond the singlemode regime helps solve the issue of high propagation loss and also significantly reduces the random phase errors of light due to the random variations of waveguide dimensions. In particularity it enables silicon photonic devices with enhanced performances, which paves the way for new-generation silicon photonics realizing the large-scale photonic integration.