Reconfigurable optomechanical circulator and directional amplifier

TL;DR

This paper demonstrates a reconfigurable optomechanical device that functions as a circulator or directional amplifier, enabling non-reciprocal signal routing in photonic and microwave circuits without magnetic materials.

Contribution

It introduces a reconfigurable nonreciprocal device using optomechanical interactions, combining reconfigurability, non-reciprocity, and active properties in a single structure.

Findings

Device can switch between circulator and amplifier modes

Exhibits significant reconfigurability and non-reciprocal behavior

Applicable to photonic, microwave, and acoustic circuits

Abstract

Non-reciprocal devices, which allow the non-reciprocal signal routing, serve as the fundamental elements in photonic and microwave circuits and are crucial in both classical and quantum information processing. The radiation-pressure-induced coupling between light and mechanical motion in traveling wave resonators has been exploited to break the Lorentz reciprocity, realizing non-reciprocal devices without magnetic materials. Here, we experimentally demonstrate a reconfigurable nonreciprocal device with alternative functions of either a circulator or a directional amplifier via the optomechanically induced coherent photon-phonon conversion or gain. The demonstrated device exhibits considerable flexibility and offers exciting opportunities for combining reconfigurability, non-reciprocity and active properties in single photonic structures, which can also be generalized to microwave as well as acoustic circuits.