TY - JOUR
T1 - Silicon photonic acoustic detector (SPADE) using a silicon nitride microring resonator
AU - Nagli, Michael
AU - Moisseev, Ron
AU - Suleymanov, Nathan
AU - Kaminski, Eitan
AU - Hazan, Yoav
AU - Gelbert, Gil
AU - Goykhman, Ilya
AU - Rosenthal, Amir
N1 - Publisher Copyright:
© 2023
PY - 2023/8
Y1 - 2023/8
N2 - Silicon photonics is an emerging platform for acoustic sensing, offering exceptional miniaturization and sensitivity. While efforts have focused on silicon-based resonators, silicon nitride resonators can potentially achieve higher Q-factors, further enhancing sensitivity. In this work, a 30 µm silicon nitride microring resonator was fabricated and coated with an elastomer to optimize acoustic sensitivity and signal fidelity. The resonator was characterized acoustically, and its capability for optoacoustic tomography was demonstrated. An acoustic bandwidth of 120 MHz and a noise-equivalent pressure of ∼ 7 mPa/Hz1/2 were demonstrated. The spatially dependent impulse response agreed with theoretical predictions, and spurious acoustic signals, such as reverberations and surface acoustic waves, had a marginal impact. High image fidelity optoacoustic tomography of a 20 µm knot was achieved, confirming the detector's imaging capabilities. The results show that silicon nitride offers low signal distortion and high-resolution optoacoustic imaging, proving its versatility for acoustic imaging applications.
AB - Silicon photonics is an emerging platform for acoustic sensing, offering exceptional miniaturization and sensitivity. While efforts have focused on silicon-based resonators, silicon nitride resonators can potentially achieve higher Q-factors, further enhancing sensitivity. In this work, a 30 µm silicon nitride microring resonator was fabricated and coated with an elastomer to optimize acoustic sensitivity and signal fidelity. The resonator was characterized acoustically, and its capability for optoacoustic tomography was demonstrated. An acoustic bandwidth of 120 MHz and a noise-equivalent pressure of ∼ 7 mPa/Hz1/2 were demonstrated. The spatially dependent impulse response agreed with theoretical predictions, and spurious acoustic signals, such as reverberations and surface acoustic waves, had a marginal impact. High image fidelity optoacoustic tomography of a 20 µm knot was achieved, confirming the detector's imaging capabilities. The results show that silicon nitride offers low signal distortion and high-resolution optoacoustic imaging, proving its versatility for acoustic imaging applications.
KW - Microring silicon-photonics acoustic detector
KW - MRR-SPADE
KW - Optical acoustic detector
KW - Optoacoustic imaging
KW - Photoacoustic imaging
KW - Silicon nitride acoustic detector
KW - Silicon-photonics acoustic detector
KW - SPADE
UR - http://www.scopus.com/inward/record.url?scp=85164238872&partnerID=8YFLogxK
U2 - 10.1016/j.pacs.2023.100527
DO - 10.1016/j.pacs.2023.100527
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AN - SCOPUS:85164238872
SN - 2213-5979
VL - 32
JO - Photoacoustics
JF - Photoacoustics
M1 - 100527
ER -