Gas sensing properties of hematite nanoparticles synthesized different techniques.

The synthesis techniques used for metal oxide semiconductors strongly influence their chemical, physical and gas sensing characteristics. In this context, hematite (α-FeO) nanoparticles (NPs) were synthesized using two different techniques, namely, sol-gel (named H) and Pechini sol-gel (named H). The average crystallite size and surface area were 15 nm and 76 m g and 20 nm and 57 m g for H and H, respectively. Morphological studies showed that the H material was composed of ellipsoid-shaped particles, while the H material had peanut-shaped particles with open pores and channels. The comparison between the sensing performances of H and H toward ethanol indicated H to be a better sensing material for ethanol detection. The H sensor exhibited a response of 12 toward 500 ppm ethanol at 250 °C, a fast response time of 5 s and excellent selectivity. The enhanced characteristics were mainly related to the peculiar morphology with a porous nature, which led to more gas adsorption and diffusion. In addition to shape influence, the size of NPs also has an effect on the gas sensing performance. In fact, a decrease in the crystallite size led to an increase in the surface area of the material where the gas molecule-sensing layer interaction took place. The increase in the surface area created more interaction sites, and thus the sensitivity was improved. From these results, the H sensor can be regarded as a promising candidate for ethanol detection.