Capacitive Ammonia Sensor Based on Graphene Oxide/Polyaniline Nanocomposites

Toxic and irritant gases such as ammonia in enclosure space could destroy the respiratory system with an unobtrusive way. Monitoring high-risk gases are imperative when humans expose in a vulnerable environment with unpredictable gases. Capacitive sensors are supposed to be an ideal choice applying to contactless gas sensing in enclosed space. This research develops an innovative model based on barrier capacitance theory for capacitive ammonia sensor. A capacitive ammonia sensor based on graphene oxide/polyaniline (GO/PANI) nanocomposites, which can be attached to enclosure space (pipes, storage tanks, etc.), is manufactured and exhibits high sensitivity (49.3 x 10(-5) ppm) and fast response (approximate to 200 s) in the ammonia concentration range of 0-100 ppm. In particular, GO/PANI nanocomposites are modeled as barrier capacitance. The model of ammonia sensor is described as width variation of space charge region in GO/PANI barrier capacitance which is caused by electron injection from adsorbed ammonia molecule. Variation trend of the model is consistent with the experimental results. Maximum deviation is limited to 9.25% in ammonia concentration range of 0-100 ppm between theoretical and experimental results. The model is able to accomplish the accurate quantitative analysis for capacitive ammonia sensors and provides an exhilarating enlightenment for other capacitive gas sensors.

Automated summary

Gas sensing in enclosed spaces is crucial, and capacitive ammonia sensors based on GO/PANI nanocomposites exhibit high sensitivity and fast response time. The model describes the sensor by variations in width of the space charge region caused by hole injection, with theoretical and experimental results matching closely.