Anatase TiO 2 nanoparticles were produced by flame spray pyrolysis (FSP) and characterized by transmission/scanning electron microscopy, X-ray diffraction and nitrogen adsorption. Thick films (30-50 µm) of these powders were prepared by drop-coating technique and tested for sensing of acetone, isoprene and ethanol at 500 °C in dry N 2 /O 2. A high n-type sensor signal was recorded at ppm levels of these organic vapors with fast response and recovery times. Heat-treatment at 900 °C caused a nearly complete anatase to rutile transformation and a transition to p-type sensing behavior. The rutile sensor had a poor signal to all hydrocarbons tested and considerably longer recovery times.
Sensing the presence of particular gases in harsh environments, such as at high temperatures, poses challenges
in the choice of materials as well as in measurements of the appropriate sensing-related property of the material.
In this study, we examine the sensing of carbon monoxide (CO) in a nitrogen background at temperatures up
to 600 °C using the anatase phase of TiO2 as the sensing material. In particular, the change in resistance of
anatase is used to detect the presence of CO. Copper oxide (CuO) is added to anatase to increase the sensitivity
toward CO detection. However, the presence of CuO led to partial transformation of anatase to rutile at
temperatures of 800 °C used for bonding the sensor material to the sensing platform. By adding La2O3 to the
CuO/anatase, the anatase phase is maintained under all thermal treatments. Diffuse reflectance infrared
spectroscopy is used to examine the mechanism of CO oxidation. Interaction of lanthanum with the anatase
increased the reactivity of the anatase surface toward CO. In addition, the presence of CuO led to increased
adsorption of CO as well as enhanced desorption of CO2, explaining the enhancement of the sensitivity of
the CuO-containing anatase toward sensing of CO. Electron microscopy has provided information on the
microstructure of the sensor material. An effective medium approximation theory is used to model the observed
resistivity data over the temperature range 400−600 °C. The energies of adsorption of CO and the reaction
of CO with adsorbed oxygen to form CO2 are extracted. These values are consistent with the role of CuO
acting as a catalyst. This study demonstrates that anatase doped with lanthanum along with the presence of
surface/CuO is an effective sensor for CO at temperatures as high as 600 °C.
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