Inverse-designed photonic circuits for fully passive, bias-free Kerr-based nonreciprocal transmission and routing

TL;DR

This paper demonstrates a fully passive, bias-free, broadband nonreciprocal photonic device using Kerr nonlinear resonators, enabling integrated optical isolation and routing suitable for chip-scale applications like LIDAR.

Contribution

It introduces a novel cascaded Fano-Lorentzian resonator system that overcomes previous limitations, enhancing nonreciprocal bandwidth, insertion loss, and power range for integrated photonics.

Findings

Achieved broadband, bias-free nonreciprocal transmission using Kerr resonators.

Implemented an on-chip all-optical router for frequency combs.

Significantly improved device performance over existing solutions.

Abstract

Nonreciprocal devices such as isolators and circulators are key enabling technologies for communication systems, both at microwave and optical frequencies. While nonreciprocal devices based on magnetic effects are available for free-space and fibre-optic communication systems, their on-chip integration has been challenging, primarily due to the concomitant high insertion loss, weak magneto-optical effects, and material incompatibility. We show that Kerr nonlinear resonators can be used to achieve all-passive, low-loss, bias-free, broadband nonreciprocal transmission and routing for applications in photonic systems such as chip-scale LIDAR. A multi-port nonlinear Fano resonator is used as an on-chip, all-optical router for frequency comb based distance measurement. Since time-reversal symmetry imposes stringent limitations on the operating power range and transmission of a single nonlinear resonator, we implement a cascaded Fano-Lorentzian resonator system that overcomes these limitations and significantly improves the insertion loss, bandwidth and non-reciprocal power range of current state-of-the-art devices. This work provides a platform-independent design for nonreciprocal transmission and routing that are ideally suited for photonic integration.