Ultracompact 4H-silicon carbide optomechanical resonator with $f_m\cdot Q_m$ exceeding $10^{13}$ Hz

TL;DR

This paper demonstrates a low-loss, ultracompact 4H-SiC optomechanical resonator with a record-high $f_m\cdot Q_m$ product, enabling efficient room-temperature optomechanical applications on a chip-scale platform.

Contribution

The work introduces the first integrated 4H-SiC-on-insulator optomechanical resonator with high performance and low optical loss, overcoming fabrication challenges in SiC nanostructures.

Findings

Achieved $f_m$ of 0.95 GHz and $Q_m$ of 1.92×10^4.

$f_m\cdot Q_m$ product exceeds 10^13 Hz.

Enabled coherent regenerative optomechanical oscillations at low power.

Abstract

Silicon carbide (SiC) has great potential for optomechanical applications due to its outstanding optical and mechanical properties. However, challenges associated with SiC nanofabrication have constrained its adoption in optomechanical devices, as embodied by the considerable optical loss or lack of integrated optical access in existing mechanical resonators. In this work, we overcome such challenges and demonstrate a low-loss, ultracompact optomechanical resonator in an integrated 4H-SiC-on-insulator (4H-SiCOI) photonic platform for the first time. Based on a suspended $4.3$-$\mu$m-radius microdisk, the SiC optomechanical resonator features low optical loss ($<1$ dB/cm), a high mechanical frequency $f_m$ of $0.95 \times 10^9$ Hz, a mechanical quality factor $Q_m$ of $1.92\times10^4$, and a footprint of $<1\times 10^{-5}$ mm$^2$. The corresponding $f_m\cdot Q_m$ product is estimated to be $1.82 \times 10^{13}$ Hz, which is among the highest reported values of optomechanical cavities tested in an ambient environment at room temperature. In addition, the strong optomechanical coupling in the SiC microdisk enables coherent regenerative optomechanical oscillations at a threshold optical dropped power of 14 $\mu$W, which also supports efficient harmonic generation at increased power levels. With such competitive performance, we envision a range of chip-scale optomechanical applications to be enabled by the low-loss 4H-SiCOI platform.