Amorphous Silicon-Carbide Photonics for Ultrasound Imaging

TL;DR

This paper introduces amorphous silicon carbide as a new material for optical ultrasound sensors, demonstrating high sensitivity, miniaturization, and suitability for high-resolution imaging applications.

Contribution

It presents the first implementation of a-SiC in optical ultrasound sensors, achieving high sensitivity and integration capabilities for advanced imaging.

Findings

Maximum optical finesse of 1320 achieved

Intrinsic sensitivity of 78 fm/kPa demonstrated

Noise equivalent pressure density below 55 mPa/√Hz

Abstract

Photonic ultrasound sensors offer unparalleled potential for improving spatial and temporal resolution in ultrasound imaging applications due to their size-independent noise figure, high sensitivity, and broad bandwidth characteristics. The exploration of optical materials in ultrasound sensing has attracted significant interest due to their potential to further enhance device performance, fabrication compatibility, and long-term stability. This work introduces amorphous silicon carbide (a-SiC) as a material for optical ultrasound sensing. a-SiC offers a balanced combination of optical confinement, low propagation loss, and high material stability, enabling sensitive and miniaturized microring sensors. We demonstrate a compact ultrasound detection system with a linear array of 20 transducers coupled to a single bus waveguide. The sensors feature a maximum optical finesse of 1320 and an intrinsic platform sensitivity of 78 fm/kPa, leading to a noise equivalent pressure density below 55 $\mathrm{mPa}/\sqrt{\mathrm{Hz}}$, which is calibrated to a hydrophone from 3.36 MHz to 30 MHz. Additionally, we perform high-resolution ultrasound imaging of fine structures, highlighting the viability of these sensors in real-world applications. Moreover, its low deposition temperature allows a-SiC material for optical ultrasound sensors to be integrated on most substrates. These results position a-SiC as a promising material for optical ultrasound sensing, offering a miniaturized, low-loss, and high-sensitivity solution for next-generation photoacoustic imaging applications.