CMOS–MEMS VOC sensors functionalized via inkjet polymer deposition for high-sensitivity acetone detection

CMOS–MEMS microresonators have become excellent candidates for developing portable chemical VOC sensing systems thanks to their extremely large mass sensitivity, extraordinary miniaturization capabilities, and on-chip integration with CMOS circuitry to operate as a self-sustained oscillator. This pa...

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Bibliographic Details
Published in:Lab on a chip 2021-09, Vol.21 (17), p.3307-3315
Main Authors: Perelló-Roig, Rafel, Verd, Jaume, Bota, Sebastià, Soberats, Bartomeu, Costa, Antonio, Segura, Jaume
Format: Article
Language:English
Subjects:
Acetone
Circuits
CMOS
Deposition
Flexing
Fluid dynamics
Fluid flow
Microelectromechanical systems
Miniaturization
Resonators
Sensitivity
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Summary:CMOS–MEMS microresonators have become excellent candidates for developing portable chemical VOC sensing systems thanks to their extremely large mass sensitivity, extraordinary miniaturization capabilities, and on-chip integration with CMOS circuitry to operate as a self-sustained oscillator. This paper presents two 4-anchored MEMS plate resonators, with a resonance frequency of 2.2 MHz and 380 kHz, fabricated together with the required circuitry using a commercial 0.35 μm CMOS technology and then coated with poly-4-vinylheduorocumyl alcohol (P4V) via inkjet deposition. Such P4V constitutes a functionalization layer for specific acetone detection as a key step in the development of an integrated device for non-invasive diabetes diagnosis through exhaled human breath. The coated sensor system has been proven to increase the acetone injection response by 6-times compared to the uncoated platform and shows a cross-sensitivity to butane of 1 : 11. Experimental data show an acetone sensitivity of −0.012 ppm Hz −1 in the best case that, together with a measured frequency Allan deviation of 0.32 ppm, provides an expected limit of detection as low as 20 ppb of acetone. Additionally, this work presents an alternative resonator design with folded flexure anchors that provide a drastic reduction of the sensor temperature sensitivity and mitigate the impact of a fluid flow inherent to the calibration system.
ISSN:1473-0197
1473-0189
DOI:10.1039/d1lc00484k