Quaternary Oxidized Carbon Nanohorns -Based Nanohybrid as Sensing Layer for Room Temperature Resistive Ethanol Sensing

Quaternary Oxidized Carbon Nanohorns -Based Nanohybrid as Sensing Layer for Room Temperature Resistive Ethanol Sensing

We report the ethanol sensing response of a resistive sensor employing a sensing layer based on a quaternary nanohybrid comprising oxidized carbon nanohorns, graphene oxide, SnO 2 , and polyvinylpyrrolidone, at 1/1/1/1 w/w/w/w mass ratio. The sensing device includes a flexible polyimide substrate an...

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Bibliographic Details
Published in:2023 International Semiconductor Conference (CAS) pp. 67 - 70
Main Authors: Serban, Bogdan-Catalin, Dumbravescu, Niculae, Buiu, Octavian, Bumbac, Marius, Brezeanu, Mihai, Cobianu, Cornel, Marinescu, Roxana, Pachiu, Cristina, Avramescu, Viorel, Nicolescu, Cristina-Mihaela, Comanescu, Florin
Format: Conference Proceeding
Language:English
Published: IEEE 11-10-2023
Subjects:
Chemoresistive ethanol sensor
Electrodes
Ethanol
Graphene oxide
HSAB principle
Linearity
Oxidized carbon nanohorns
Polyimides
Resistance
Sensitivity
Temperature measurement
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Summary:We report the ethanol sensing response of a resistive sensor employing a sensing layer based on a quaternary nanohybrid comprising oxidized carbon nanohorns, graphene oxide, SnO 2 , and polyvinylpyrrolidone, at 1/1/1/1 w/w/w/w mass ratio. The sensing device includes a flexible polyimide substrate and interdigital transducer-like electrodes. The sensing film is deposited via the drop-casting method on the sensing structure. The sensing layer morphology and composition are investigated through Scanning Electron Microscopy and Raman spectroscopy. The developed chemoresistive structure shows good sensitivity to concentrations of alcohol vapors varying in the range of 0.008 - 0.177 mg/cm 3 . The resistance of the proposed sensing structure increases over almost the entire range of measured ethanol concentration, with a maximum at an alcohol vapor concentration of 0.16 mg/cm 3 . The ethanol sensitivity of the proposed sensing layer is thoroughly explained by 2 theories, including the Hard-Soft Acid-Base principle.
ISSN:2377-0678
DOI:10.1109/CAS59036.2023.10303659