Polymeric cantilevered piezotronic strain microsensors processed by Atomic Layer Deposition

[Display omitted] •Proof-of-concept of the piezotronic microsensors shaped to cantilevers by the mean of atomic force microscopy (AFM) force spectroscopy.•Transducing capability demonstrated for applied strains inferior to 1 %, for both DC and AC modulations.•Highlighting of three main sources of no...

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Veröffentlicht in:	Sensors and actuators. A. Physical. 2020-11, Vol.315, p.112280, Article 112280
Hauptverfasser:	Joly, Raoul, Girod, Stéphanie, Adjeroud, Noureddine, Nguyen, Tai, Grysan, Patrick, Klein, Sébastien, Menguelti, Kevin, Vergne, Christèle, Polesel-Maris, Jérôme
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Schlagworte:	Atomic Layer Deposition ALD Atomic layer epitaxy Electrical junctions electromechanical transducer Energy consumption Foils Frequency response Linearity Microelectrodes Noise sensitivity Offset printing piezotronic Platinum Power consumption Schottky junctions Sensors Strain sensor Thin films Wurtzite Zinc oxide Zinc oxides
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container_title	Sensors and actuators. A. Physical.
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creator	Joly, Raoul Girod, Stéphanie Adjeroud, Noureddine Nguyen, Tai Grysan, Patrick Klein, Sébastien Menguelti, Kevin Vergne, Christèle Polesel-Maris, Jérôme
description	[Display omitted] •Proof-of-concept of the piezotronic microsensors shaped to cantilevers by the mean of atomic force microscopy (AFM) force spectroscopy.•Transducing capability demonstrated for applied strains inferior to 1 %, for both DC and AC modulations.•Highlighting of three main sources of noise in piezotronic strain sensors.•Maskless microfabrication process flow using laser lithography to process electronics on a flexible polyimide foil.•Optimization of a thin zinc oxide (ZnO) layer by thermal Atomic Layer Deposition (ALD) for Schottky junctions. We propose an original and reliable method for processing cantilevered piezotronic strain microsensors based on diode junctions made of dominant wurtzite zinc oxide (ZnO) polycrystalline thin film by atomic layer deposition (ALD). These strain sensitive microsensors are integrated into millimetre-sized polyimide cantilevers by means of maskless laser lithography on the polymer foil, where the zinc oxide thin film is microstructured on top of patterned interdigitated platinum microelectrodes. We show how the structural and transducing properties are strongly influenced by the ALD deposition parameters, leading to the expected Schottky barrier modulation by electromechanical coupling. The linearity, sensitivity, frequency response and noise figure of the created piezotronic strain sensors are reported, leading to measured gauge factors as high as 150. Electrical power consumption inferior to 50 μW is reported.
doi_str_mv	10.1016/j.sna.2020.112280
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We propose an original and reliable method for processing cantilevered piezotronic strain microsensors based on diode junctions made of dominant wurtzite zinc oxide (ZnO) polycrystalline thin film by atomic layer deposition (ALD). These strain sensitive microsensors are integrated into millimetre-sized polyimide cantilevers by means of maskless laser lithography on the polymer foil, where the zinc oxide thin film is microstructured on top of patterned interdigitated platinum microelectrodes. We show how the structural and transducing properties are strongly influenced by the ALD deposition parameters, leading to the expected Schottky barrier modulation by electromechanical coupling. The linearity, sensitivity, frequency response and noise figure of the created piezotronic strain sensors are reported, leading to measured gauge factors as high as 150. 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A. Physical.</title><description>[Display omitted] •Proof-of-concept of the piezotronic microsensors shaped to cantilevers by the mean of atomic force microscopy (AFM) force spectroscopy.•Transducing capability demonstrated for applied strains inferior to 1 %, for both DC and AC modulations.•Highlighting of three main sources of noise in piezotronic strain sensors.•Maskless microfabrication process flow using laser lithography to process electronics on a flexible polyimide foil.•Optimization of a thin zinc oxide (ZnO) layer by thermal Atomic Layer Deposition (ALD) for Schottky junctions. We propose an original and reliable method for processing cantilevered piezotronic strain microsensors based on diode junctions made of dominant wurtzite zinc oxide (ZnO) polycrystalline thin film by atomic layer deposition (ALD). These strain sensitive microsensors are integrated into millimetre-sized polyimide cantilevers by means of maskless laser lithography on the polymer foil, where the zinc oxide thin film is microstructured on top of patterned interdigitated platinum microelectrodes. We show how the structural and transducing properties are strongly influenced by the ALD deposition parameters, leading to the expected Schottky barrier modulation by electromechanical coupling. The linearity, sensitivity, frequency response and noise figure of the created piezotronic strain sensors are reported, leading to measured gauge factors as high as 150. 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subjects	Atomic Layer Deposition ALD Atomic layer epitaxy Electrical junctions electromechanical transducer Energy consumption Foils Frequency response Linearity Microelectrodes Noise sensitivity Offset printing piezotronic Platinum Power consumption Schottky junctions Sensors Strain sensor Thin films Wurtzite Zinc oxide Zinc oxides
title	Polymeric cantilevered piezotronic strain microsensors processed by Atomic Layer Deposition
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