Abstract
Abstract. The impact of a hexamethyldisiloxane (HMDSO) treatment on the response of doped SnO2 sensors is investigated for acetone, carbon monoxide and hydrogen. The sensor was operated in temperature cycles based on the DSR concept (differential surface reduction). According to this concept, the rate constants for the reduction and oxidation of the surface after fast temperature changes can be evaluated and used for quantification of reducing gases as well as quantification and compensation of sensor poisoning by siloxanes, which is shown in this work. Increasing HMDSO exposure reduces the rate constants and therefore the sensitivity of the sensor more and more for all processes. On the other hand, while the rate constants for acetone and carbon monoxide are reduced nearly to zero already for short treatments, the hydrogen sensitivity remains fairly stable, which greatly increases the selectivity. During repeated HMDSO treatment the quasistatic sensitivity, i.e. equilibrium sensitivity at one point during the temperature cycle, rises at first for all gases but then drops rapidly for acetone and carbon monoxide, which can also be explained by reduced rate constants for oxygen chemisorption on the sensor surface when considering the generation of surface charge.
Highlights
Exposure to siloxane is known to change the properties of metal oxide semiconductor (MOS) gas sensors in terms of response time, sensitivity and selectivity (Williams and Pratt, 1998; Schüler et al, 2015)
The temperature-cycled operation (TCO) temperature during the first low-temperature phase (150 ◦C) is too low to yield a significant reduction of surface charge by acetone and hydrogen, so a significant relaxation is only observed for carbon monoxide
Taking the total siloxane concentration that is not exceeded in 90 % of investigated homes in the study by Hofmann and Plieninger (2008), this first treatment step in our study represents a dose corresponding to 0.5–1 year of operation in an indoor environment, which might be justifiable for a low-cost sensor
Summary
Exposure to siloxane is known to change the properties of metal oxide semiconductor (MOS) gas sensors in terms of response time, sensitivity and selectivity (Williams and Pratt, 1998; Schüler et al, 2015) These changes are caused by the decomposition of the siloxanes on the hot sensor surface leading to the formation of non-volatile reaction products like polymers or silica (Rücker and Kümmerer, 2015) and to a decrease in reactivity, e.g. due to a reduction of catalytic activity of the sensor surface. Due to the increasing abundance of cyclic siloxanes, the German environmental agency UBA proposed a guideline limit value of 0.4 mg m−3 of cyclic siloxanes in room air
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