Understanding on the effect of morphology towards the hydrogen and carbon monoxide sensing characteristics of tin oxide sensing elements

Though the gas sensing properties of atmospheric plasma sprayed tungsten oxide, zinc oxide, titanium oxide, tin oxide and copper oxide coatings were well investigated, reports comparing sensing characteristics of plasma sprayed sensor thick film coating with its bulk counterpart are hardly found in the literature. This work attempts to compare hydrogen and carbon monoxide sensing characteristics, namely gas response, response time, re-covery time of plasma sprayed tin dioxide thick film with tin dioxide bulk sensor. Gas response in the presence of hydrogen gas (23-81%) was superior to that of carbon mon-oxide gas (19-79%). An attempt was made to understand plausible reason behind superior hydrogen gas response. Thus, gas response as a function of temperature was simulated using a gas diffusion equation for hydrogen and carbon monoxide gases. Estimated pa-rameters, namely, activation energy of transduction and first order kinetics were corre-lated with sensor microstructure and experimental gas response values. For hydrogen sensing, shorter response time (30-138 s) and recovery time (118-161 s) of thick film as compared to response time (64-234 s) and recovery time (183-196 s) of bulk sensor was correlated with microstructure of sensory elements. It was observed that tin dioxide thick film, owing to its porous morphology with small-sized particulates exhibited superior hydrogen gas response, short response time and recovery time as compared to its bulk counterpart. (c) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

This study compared the gas sensing characteristics of plasma sprayed tin dioxide thick film with tin dioxide bulk sensor in the presence of hydrogen and carbon monoxide gases. The results showed that the thick film exhibited superior hydrogen gas response, shorter response time, and recovery time, which were attributed to its porous morphology and small-sized particulates.