Abstract
The application of gas sensors in breath analysis is an important trend in the early diagnostics of different diseases including lung cancer, ulcers, and enteric infection. However, traditional methods of synthesis of metal oxide gas-sensing materials for semiconductor sensors based on wet sol-gel processes give relatively high sensitivity of the gas sensor to changing humidity. The sol-gel process leading to the formation of superficial hydroxyl groups on oxide particles is responsible for the strong response of the sensing material to this factor. In our work, we investigated the possibility to synthesize metal oxide materials with reduced sensitivity to water vapors. Dry synthesis of SnO2 nanoparticles was implemented in gas phase by spark discharge, enabling the reduction of the hydroxyl concentration on the surface and allowing the production of tin dioxide powder with specific surface area of about 40 m2/g after annealing at 610 °C. The drop in sensor resistance does not exceed 20% when air humidity increases from 40 to 100%, whereas the response to 100 ppm of hydrogen is a factor of 8 with very short response time of about 1 s. The sensor response was tested in mixtures of air with hydrogen, which is the marker of enteric infections and the marker of early stage fire, and in a mixture of air with lactate (marker of stomach cancer) and ammonia gas (marker of Helicobacter pylori, responsible for stomach ulcers).
Highlights
One of most important obstacles limiting the application of metal oxide (MOX) semiconductor gas sensors for contaminant trace detection is the humidity dependence of the sensor response.This restriction is well pronounced in the case of the application of gas sensors for the analysis of human breath, where the relative humidity of air is not constant and can reach ~100%
The histogram obtained from the analysis of transmission electron microscopy (TEM) images of primary particles constituting the as-synthesized powder is well described by a log-normal distribution with the modal size of about 4.7 nm (Figure 5A)
It was demonstrated that it is possible to free the surface from hydroxyl groups, to reconstruct the surface of tin dioxide particles in a way that prevents chemisorption of new hydroxyl groups by the surface, but to do this without strong crystallite growth and a strong decrease in target gas sensitivity
Summary
One of most important obstacles limiting the application of metal oxide (MOX) semiconductor gas sensors for contaminant trace detection is the humidity dependence of the sensor response. This restriction is well pronounced in the case of the application of gas sensors for the analysis of human breath, where the relative humidity of air is not constant and can reach ~100%. The minimum methane concentration which could be measured without special humidity compensation is equal to about 500 ppm within 2σ accuracy This makes the application of MOX sensors in modern safety systems very difficult
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