A high-temperature mixed potential CO gas sensor forin situcombustion control

Anin situ, accurate and robust sensor that can sustain a high temperature of above 1000 degrees C is needed for on-site combustion monitoring because it can give real-time and local data to the control system to adjust the overall combustion efficiency. In this work, we find that nickel oxide (NiO) is a promising sensing material for CO which is a direct indicator of the status of the combustion process of a power plant. Under the conditions of 0.5-3% O(2)and 1000 degrees C, the fabricated yttrium-stabilized zirconia (YSZ)-based mixed potential sensor using porous NiO demonstrates good sensitivity to CO, showing a signal as high as 36 mV to 1000 ppm CO. The effects of gas transport, structure and geometry of the NiO electrode on the sensing performance are studied. Results show that fast gas transport is much beneficial to improved sensitivity. NiO having a porous structure is much more sensitive to CO than that having a dense structure. But thet(90)(time to achieve 90% final signal magnitude) of the former is much longer due to slower gas diffusion inside the pores. It's worth noting that the NiO sensor exhibits a positive relationship with the CO content, opposite to other reported results of mixed potential sensors to detect CO. We find that this might be due to the electrochemical reduction, instead of oxidation of CO during the interaction with NiO at 1000 degrees C. Selectivity tests on how CO2, CH(4)and steam affect CO sensing are also demonstrated. NiO is insensitive to even 10% CO2. CH(4)does not shift the average value of the CO sensing response. However, it makes the sensing signal fluctuate more intensively. 2% steam exerts a great influence on NiO sensitivity to CO: it magnifies the sensitivity of the porous NiO electrode to a low CO range of 0-100 ppm, but inhibits its sensitivity to a CO range of 100 ppm to 1000 ppm. Finally, an 11 day stability test demonstrates the promising stability property of the proposed NiO-based YSZ sensor.