Design and Characterisation of a Non-Contact Flexible Sensor Array for Electric Potential Imaging Applications

Capacitive non-contact imaging of electric fields and potentials with micro-metre resolution can provide relevant insights into material characterisation, structural analysis, electrostatic charge imaging and bio-sensing applications. However, scanning electric potential microscopes have been confin...

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Bibliographic Details
Published in:IEEE sensors journal 2021-12, Vol.21 (23), p.26328-26336
Main Authors: Pouryazdan, Arash, Costa, Julio C., Garcia-Garcia, Leonardo, Lugoda, Pasindu, Prance, Robert J., Prance, Helen, Munzenrieder, Niko
Format: Article
Language:English
Subjects:
Capacitive sensors
Electric contacts
Electric fields
Electric potential
electric potential imaging
Electric variables measurement
Electrification
Electrostatic charge
Electrostatic shielding
Flexible components
Flexible electronics
Imaging
Microscopes
Probes
Sensor array
Sensor arrays
Sensor phenomena and characterization
Sensors
Spatial resolution
Structural analysis
Substrates
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Summary:Capacitive non-contact imaging of electric fields and potentials with micro-metre resolution can provide relevant insights into material characterisation, structural analysis, electrostatic charge imaging and bio-sensing applications. However, scanning electric potential microscopes have been confined to rigid and single-probe devices, making them slow, prone to mechanical damage and complex to fabricate. In this work, we present the design and characterisation of a novel 5-element flexible array of electric potential probes with spatial resolution down to 20 \mu \text{m} to speed up the scanning time. This was achieved by combining flexible thin-film probes for active guarding and shielding with state-of-the art discrete conditioning circuits. The potential of this approach is showcased by using the fabricated array to image latent fingerprints deposited on an insulating surface by contact electrification, obtain the surface topography of conductive samples and to visualise local dielectric variations.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2021.3064276