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Sensitive label-free and compact ultrasonic sensor based on double silicon-on-insulator slot micro-ring resonators

We propose a new label-free ultrasonic sensor, which comprises a slot wave-guide and double silicon-on-insulator (SOI) slot micro-ring resonators. The all-optical sensors do not suffer from electromagnetic interference. We choose to integrate a silicon slot double micro-ring (SDMR) resonators in an acoustically resonant membrane. Optimization of the several key structural parameters is investigated to achieve the mode-field distributions of transmission spectrum based on Comsol Multiphysics software. Our numerical studies show that the proposed ultrasonic sensor offers higher sensitivity and a larger detection frequency range than conventional piezoelectric based ultrasound transducer. For a SDMR system with an area of 15um*30um, sensitivity as high as 2453.7mv/kpa, and over a bandwidth range of 1-150MHz. The sensitivity value is 36 times higher than that of single slot micro-ring ultrasonic sensor. The theoretical-factor of the SDMR can be approximately 1.24*10^6 with bending radius of 5um. The investigation on the SDMR system is a valuable exploration of the photo-acoustic microscopy for the ultra-high Q factor and large frequency range.

preprint2022arXivOpen access
Cheng Mei ZhangChao Ying Zhao
physics.app-phphysics.optics
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Cheng Mei ZhangChao Ying Zhao

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