A Resonant Graphene NEMS Vibrometer

Daniel Moreno-Garcia; Xuge Fan; Anderson D. Smith; Max C. Lemme; Vincenzo Messina; Cristina Martin-Olmos; Frank Niklaus; Luis Guillermo Villanueva

doi:10.1002/smll.202201816

A Resonant Graphene NEMS Vibrometer

Daniel Moreno-Garcia
, Xuge Fan
, Anderson D. Smith
, Max C. Lemme
, Vincenzo Messina
, Cristina Martin-Olmos
, Frank Niklaus^*
, Luis Guillermo Villanueva^*

^*Corresponding author for this work

Swiss Federal Institute of Technology Lausanne
KTH Royal Institute of Technology
Beijing Institute of Technology
Chalmers University of Technology
RWTH Aachen University
Swiss Integrative Center for Human Health

Research output: Contribution to journal › Article › peer-review

22 Citations (Scopus)

Abstract

Measuring vibrations is essential to ensuring building structural safety and machine stability. Predictive maintenance is a central internet of things (IoT) application within the new industrial revolution, where sustainability and performance increase over time are going to be paramount. To reduce the footprint and cost of vibration sensors while improving their performance, new sensor concepts are needed. Here, double-layer graphene membranes are utilized with a suspended silicon proof demonstrating their operation as resonant vibration sensors that show outstanding performance for a given footprint and proof mass. The unveiled sensing effect is based on resonant transduction and has important implications for experimental studies involving thin nano and micro mechanical resonators that are excited by an external shaker.

Original language	English
Article number	2201816
Journal	Small
Volume	18
Issue number	28
DOIs	https://doi.org/10.1002/smll.202201816
Publication status	Published - 14 Jul 2022
Externally published	Yes

Keywords

graphene
laser doppler vibrometry
nano-electromechanical (NEMS)
resonators
vibration

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10.1002/smll.202201816

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abstract = "Measuring vibrations is essential to ensuring building structural safety and machine stability. Predictive maintenance is a central internet of things (IoT) application within the new industrial revolution, where sustainability and performance increase over time are going to be paramount. To reduce the footprint and cost of vibration sensors while improving their performance, new sensor concepts are needed. Here, double-layer graphene membranes are utilized with a suspended silicon proof demonstrating their operation as resonant vibration sensors that show outstanding performance for a given footprint and proof mass. The unveiled sensing effect is based on resonant transduction and has important implications for experimental studies involving thin nano and micro mechanical resonators that are excited by an external shaker.",

keywords = "graphene, laser doppler vibrometry, nano-electromechanical (NEMS), resonators, vibration",

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AU - Moreno-Garcia, Daniel

AU - Fan, Xuge

AU - Smith, Anderson D.

AU - Lemme, Max C.

AU - Messina, Vincenzo

AU - Martin-Olmos, Cristina

AU - Niklaus, Frank

AU - Villanueva, Luis Guillermo

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N2 - Measuring vibrations is essential to ensuring building structural safety and machine stability. Predictive maintenance is a central internet of things (IoT) application within the new industrial revolution, where sustainability and performance increase over time are going to be paramount. To reduce the footprint and cost of vibration sensors while improving their performance, new sensor concepts are needed. Here, double-layer graphene membranes are utilized with a suspended silicon proof demonstrating their operation as resonant vibration sensors that show outstanding performance for a given footprint and proof mass. The unveiled sensing effect is based on resonant transduction and has important implications for experimental studies involving thin nano and micro mechanical resonators that are excited by an external shaker.

AB - Measuring vibrations is essential to ensuring building structural safety and machine stability. Predictive maintenance is a central internet of things (IoT) application within the new industrial revolution, where sustainability and performance increase over time are going to be paramount. To reduce the footprint and cost of vibration sensors while improving their performance, new sensor concepts are needed. Here, double-layer graphene membranes are utilized with a suspended silicon proof demonstrating their operation as resonant vibration sensors that show outstanding performance for a given footprint and proof mass. The unveiled sensing effect is based on resonant transduction and has important implications for experimental studies involving thin nano and micro mechanical resonators that are excited by an external shaker.

KW - graphene

KW - laser doppler vibrometry

KW - nano-electromechanical (NEMS)

KW - resonators

KW - vibration

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VL - 18

JO - Small

JF - Small

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ER -

A Resonant Graphene NEMS Vibrometer

Abstract

Keywords

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