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Main Authors: Abrahams, M. P., Martinez, J., Steeneken, P. G., Verbiest, G. J.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.09566
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author Abrahams, M. P.
Martinez, J.
Steeneken, P. G.
Verbiest, G. J.
author_facet Abrahams, M. P.
Martinez, J.
Steeneken, P. G.
Verbiest, G. J.
contents Most microphones operate by detecting the sound-pressure induced motion of a membrane. In contrast, here we introduce a microphone that operates by monitoring the sound-pressure-induced modulation of the compressibility of air. By driving a graphene membrane at its resonance frequency, the gas, that is trapped in a squeeze-film beneath it, is compressed at high frequency. Since the stiffness of the gas film depend on the air pressure, the resonance frequency of the graphene is modulated by variations in sound pressure. We demonstrate that this squeeze-film microphone principle can be used to detect sound and music by tracking the membrane's resonance frequency using a phase-locked loop (PLL). Since the sound detection principle is different from conventional devices, the squeeze-film microphone potentially offers advantages like increased dynamic range, and a lower susceptibility to pressure-induced failure and vibration-induced noise. Moreover, it might be made much smaller, as demonstrated by the microphone in this work that operates using a circular graphene membrane with an area that is more than a factor 1000 smaller than that of MEMS microphones.
format Preprint
id arxiv_https___arxiv_org_abs_2406_09566
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle The graphene squeeze-film microphone
Abrahams, M. P.
Martinez, J.
Steeneken, P. G.
Verbiest, G. J.
Applied Physics
Mesoscale and Nanoscale Physics
Most microphones operate by detecting the sound-pressure induced motion of a membrane. In contrast, here we introduce a microphone that operates by monitoring the sound-pressure-induced modulation of the compressibility of air. By driving a graphene membrane at its resonance frequency, the gas, that is trapped in a squeeze-film beneath it, is compressed at high frequency. Since the stiffness of the gas film depend on the air pressure, the resonance frequency of the graphene is modulated by variations in sound pressure. We demonstrate that this squeeze-film microphone principle can be used to detect sound and music by tracking the membrane's resonance frequency using a phase-locked loop (PLL). Since the sound detection principle is different from conventional devices, the squeeze-film microphone potentially offers advantages like increased dynamic range, and a lower susceptibility to pressure-induced failure and vibration-induced noise. Moreover, it might be made much smaller, as demonstrated by the microphone in this work that operates using a circular graphene membrane with an area that is more than a factor 1000 smaller than that of MEMS microphones.
title The graphene squeeze-film microphone
topic Applied Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2406.09566