Injection locking of optomechanical oscillators via acoustic waves

TL;DR

This paper demonstrates a novel method for injection locking of optomechanical oscillators using acoustic waves, enabling phase and frequency control without optical power modulation or physical contact, with potential applications in photonics and quantum optomechanics.

Contribution

First demonstration of acoustic wave-based injection locking of OMOs, offering a scalable, efficient, and contactless synchronization technique.

Findings

Locked two modes of a silica OMO to a PZT with -30 dBm RF power

Achieved 17 kHz tuning range without impedance matching

Method applicable to various platforms and useful for quantum studies

Abstract

Injection locking is a powerful technique for synchronization of oscillator networks and controlling the phase and frequency of individual oscillators using similar or other types of oscillators. Here, we present the first demonstration of injection locking of a radiation-pressure driven optomechanical oscillator (OMO) via acoustic waves. As opposed to previously reported techniques (based on pump modulation or direct application of a modulated electrostatic force), injection locking of OMO via acoustic waves does not require optical power modulation or physical contact with the OMO and it can easily be implemented on various platforms. Using this approach we have locked the phase and frequency of two distinct modes of a microtoroidal silica OMO to a piezoelectric transducer (PZT). We have characterized the behavior of the injection locked OMO with three acoustic excitation configurations and showed that even without proper acoustic impedance matching the OMO can be locked to the PZT and tuned over 17 kHz with only -30 dBm of RF power fed to the PZT. The high efficiency, simplicity and scalability of the proposed approach paves the road toward a new class of photonic systems that rely on synchronization of several OMOs to a single or multiple RF oscillators with applications in optical communication, metrology and sensing. Beyond its practical applications, injection locking via acoustic waves can be used in fundamental studies in quantum optomechanics where thermal and optical isolation of the OMO are critical.