Graphene Nanoplatelet-Polymer Chemiresistive Sensor Arrays for the Detection and Discrimination of Chemical Warfare Agent Simulants

A cross-reactive array of semiselective chemiresistive sensors made of polymer-graphene nanoplatelet (GNP) composite coated electrodes was examined for detection and discrimination of chemical warfare agents (CWA). The arrays employ a set of chemically diverse polymers to generate a unique response...

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Bibliographic Details
Published in:ACS sensors 2017-11, Vol.2 (11), p.1669-1678
Main Authors: Wiederoder, Michael S., Nallon, Eric C., Weiss, Matt, McGraw, Shannon K., Schnee, Vincent P., Bright, Collin J., Polcha, Michael P., Paffenroth, Randy, Uzarski, Joshua R.
Format: Article
Language:English
Subjects:
Chemical Warfare Agents - analysis
Chemical Warfare Agents - chemistry
Chemistry Techniques, Analytical - instrumentation
Graphite - chemistry
Limit of Detection
Nanocomposites - chemistry
Polymers - chemistry
Volatilization
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Summary:A cross-reactive array of semiselective chemiresistive sensors made of polymer-graphene nanoplatelet (GNP) composite coated electrodes was examined for detection and discrimination of chemical warfare agents (CWA). The arrays employ a set of chemically diverse polymers to generate a unique response signature for multiple CWA simulants and background interferents. The developed sensors’ signal remains consistent after repeated exposures to multiple analytes for up to 5 days with a similar signal magnitude across different replicate sensors with the same polymer-GNP coating. An array of 12 sensors each coated with a different polymer–GNP mixture was exposed 100 times to a cycle of single analyte vapors consisting of 5 chemically similar CWA simulants and 8 common background interferents. The collected data was vector normalized to reduce concentration dependency, z-scored to account for baseline drift and signal-to-noise ratio, and Kalman filtered to reduce noise. The processed data was dimensionally reduced with principal component analysis and analyzed with four different machine learning algorithms to evaluate discrimination capabilities. For 5 similarly structured CWA simulants alone 100% classification accuracy was achieved. For all analytes tested 99% classification accuracy was achieved demonstrating the CWA discrimination capabilities of the developed system. The novel sensor fabrication methods and data processing techniques are attractive for development of sensor platforms for discrimination of CWA and other classes of chemical vapors.
ISSN:2379-3694
2379-3694
DOI:10.1021/acssensors.7b00550