Assaf Grinberg scite author profile

Assaf Grinberg

4Publications

19Citation Statements Received

30Citation Statements Given

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Affiliations

Technion – Israel Institute of Technology

Publications

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Modeling the sensitivity dependence of silicon-photonics-based ultrasound detectors

et al. 2017

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With recent advances in optical technology, interferometric sensing has grown into a highly versatile approach for ultrasound detection, with many interferometric detectors relying on optical waveguides to achieve high levels of sensitivity and miniaturization. In this Letter, we establish a practical model for assessing the sensitivity of silicon-photonics waveguides to acoustic waves. The analysis is performed for different polarizations, waveguide dimensions, and acoustic wave types. Our model was validated experimentally in the acoustic frequency band of 1-13 MHz by measuring the sensitivities of the two polarization modes in a silicon strip waveguide. Both the experimental results and theoretical prediction show that the transverse-magnetic polarization achieves a higher sensitivity and suppression of surface acoustic waves compared to the transverse-electric polarization for the geometries studied.

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Enhanced Sensitivity of Silicon-Photonics-Based Ultrasound Detection via BCB Coating

et al. 2019

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Ultrasound detection via silicon waveguides relies on the ability of acoustic waves to modulate the effective refractive index of the guided modes. However, the low photo-elastic response of silicon and silica limits the sensitivity of conventional silicon-oninsulator sensors, in which the silicon core is surrounded by a silica cladding. In this paper, we demonstrate that the sensitivity of silicon waveguides to ultrasound may be significantly enhanced by replacing the silica over-cladding with bisbenzocyclobutene (BCB)-a transparent polymer with a high photo-elastic coefficient. In our experimental study, the response to ultrasound, in terms of the induced modulation in the effective refractive index, achieved for a BCB-coated silicon waveguide with TM polarization was comparable to values previously reported for polymer waveguides and an order of magnitude higher than the response achieved by an optical fiber. In addition, in our study, the susceptibility of the sensors to surface acoustic waves and reverberations was reduced for both TE and TM modes when the BCB over-cladding was used.

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Modeling of ultrasound detection by silicon-photonics-based sensors

Tsesses

Aronovich

Grinberg

et al. 2018

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Hybrid ultrasound-detection platform based on silicon photonics and transparent polymers (Conference Presentation)

Kumar

Hahamovich

Tsesses

et al. 2020

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Assaf Grinberg

Modeling the sensitivity dependence of silicon-photonics-based ultrasound detectors

Enhanced Sensitivity of Silicon-Photonics-Based Ultrasound Detection via BCB Coating

Modeling of ultrasound detection by silicon-photonics-based sensors

Hybrid ultrasound-detection platform based on silicon photonics and transparent polymers (Conference Presentation)

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