Abstract: To meet the requirements for high quality data capturing of metal oxide semiconductor (MOS) gas sensors, a platform is presented that can handle a large variety of sensors. Besides manufacturer modes, the platform is able to run sensors in temperature cycled operation (TCO). A system concept is presented that provides hardware modules to adapt to different MOS types like analog/digital or thin film/thick film. For analog sensors, an analog frontend with two different power variants handles the different power demands of thick film and thin film sensors. The concept and realization of the analog frontend is shown. For digital sensors, a generalized design with digital signal input sections was developed to receive data via I2C, SPI, or UART. A single microcontroller model constitutes the core of each board variant and it is flashed with a unified firmware which manages the module specific tasks. For continuity and usability, a graphical user interface (GUI) is presented that allows the user to modify measurement parameters and monitor the measurement. GUI and firmware are tuned to one another and exchange data and information to perform user commands. The validation of the accuracy of the analog temperature control is discussed and the successful usage of the system in various applications like indoor air quality (IAQ) is shown.

Abstract: Abstract. We present an equivalent circuit model for a titanium dioxide-based humidity sensor which enables discrimination of three separate contributions to the sensor impedance. The first contribution, the electronic conductance, consists of a temperature-dependent ohmic resistance. The second contribution arises from the ionic pathway, which forms depending on the relative humidity on the sensor surface. It is modeled by a constant-phase element (CPE) in parallel with an ohmic resistance. The third contribution is the capacitance of the double layer which forms at the blocking electrodes and is modeled by a second CPE in series to the first CPE. This model was fitted to experimental data between 1 mHz and 1 MHz recorded at different sensor temperatures (between room temperature and 320 ∘C) and different humidity levels. The electronic conductance becomes negligible at low sensor temperatures, whereas the double-layer capacitance becomes negligible at high sensor temperatures in the investigated frequency range. Both the contribution from the ionic pathway and from the double-layer capacitance strongly depend on the relative humidity and are, therefore, suitable sensor signals. The findings define the parameters for the development of a dedicated Fourier-based impedance spectroscope with much faster acquisition times, paving a way for impedance-based high-temperature humidity sensor systems.

Abstract: Eine nicht invasive online Überwachung von Medikamenten-Konzentrationen in der Ausatemluft kann eine hohe therapeutische Bedeutung haben. In dieser Arbeit werden kommerzielle Halbleitergassensoren, insbesondere der ENS160 von ScioSense, im temperaturzyklischen Betrieb auf Eignung zur Quantifizierung des intravenösen Anästhetikums Propofol untersucht. Der Anwendungsfall Propofol wurde ausgewählt, da hier bereits eine Korrelation zwischen Plasmakonzentration und Konzentration in der Ausatemluft nachgewiesen wurde. Basierend auf einer Laborkalibrierung mit variierender Feuchte und Ethanol-Konzentration wird ein Regressionsmodell gebildet, das den Einfluss der Störgrößen unterdrückt und die Propofol-Konzentration vorhersagen kann. Ethanol wurde als Störgas gewählt, da es zum einen im klinischen Bereich vermehrt auftritt und gleichzeitig einen großen Störeinfluss auf MOS Sensoren hat. Der Validierungsfehler liegt bei 4 ppb für einen Konzentrationsbereich von 0 ppb bis 40 ppb, was den Schluss nahe legt, dass die Sensoren prinzipiell zur Überwachung geeignet sind.

Abstract: Introduction The impact of siloxane exposure on SnO 2 based gas sensors is highly important in many applications due to the frequent occurrence of these substances in ambient air. This process is usually called poisoning since siloxane exposure leads to permanently impaired sensors, changing selectivity and decreasing sensitivity to gases [1] except for hydrogen [2] . The often observed first increase in sensitivity led to the complex interpretation of several surface sites [3]. Two independent investigations on the effect of siloxanes on the commercially available UST GGS 1530 (Umweltsensortechnik GmbH, Geschwenda, Germany) were conducted yielding the same output: the reactivity of the sensor’s surface is continuously reduced during siloxane exposure. Experimental The first investigation focused on the effects on the dynamic operation called differential surface reduction (DSR, described in [4]), where the sensor is alternating between a high temperature oxidation phase and a low temperature reduction phase, which enables the independent measurement of both processes. The rate constant for reducing gases reacting on the sensor surface is evaluated through the first derivative of the logarithmic conductivity ln(G) on the low temperature phase. Turning the DSR method around allows the evaluation of the differential surface oxidation (DSO) through the dynamic behavior of ln(G) during the high temperature phase. The second investigation targeted gas sensors for monitoring methane concentrations ( 〈 4.4 %) in harsh environments contaminated with siloxane. The measurements were performed in a gas mixing system similar to the system described in [4] consisting of mass flow controllers and valves. During the first investigation the humidity was always held at 50 % R.H, the second investigation included measurements at 0, 10 and 65 % R.H., supplied by a water bubbler at 20 °C. further described in [5]. (table 1) and increasing sensor temperature were performed, gas measurements with 2 ppm of hydrogen were conducted in between. The second investigation used the most abundant siloxane OMCTS (octamethylcyclotetrasiloxane) and the 2 l/min dilution MFC was omitted due to the low vapor pressure. The sensor was constantly operated at 400 °C. conducted, several methane concentrations and backgrounds were measured in between as seen in figure (Fig. 2). Results The main result from the first investigation on hydrogen is given in Fig. 1. Features from both DSR (middle, 300 °C) and DSO (right, 450 C°) are declining with increasing siloxane dosage, while the sensor response (left, 300 °C) shows no distinct trend. This indicates that siloxane exposure gradually slows down both surface reactions, which corresponds to a deactivation of active sites, i.e. a lower reactivity of the sensor surface, whereas the static equilibrium is shifted in different directions depending on the relative effect on hydrogen and oxygen reactivity at each treatment step. The deactivation of active surface sites can also be observed in steady state operation by an exposure to a high concentration of reducing gas, e.g. methane. The reaction (“combustion”) of methane creates excess heat reducing the heater power at constant temperature similar to a pellistor [6]. This effect is offset by the change in thermal conductivity of the surrounding gas which increases the heater power for higher methane concentrations. Siloxane exposure reduces the reaction rate and therefore the equilibrium between both effects is shifted towards thermal conductivity, thus increasing the power consumption. This is shown in Fig. 2, where the heater power difference in different gas compositions compared to dry air is plotted vs. the OMCTS dose. Results for 1 % methane in dry air shift from the combustion dominated (up to 10 ppmh OMCTS) to the thermal conductivity dominated (from 500 ppmh) region. At 65 % R.H., the thermal conductivity effect is always dominant independent of the OMCTS dosage, but also increases with siloxane exposure. Both described methods show independently that siloxane exposure decreases the reaction rates on the sensor surface affecting reduction and oxidation process, which can be exploited for sensor self-monitoring. In temperature cycled operation the resulting deterioration could be determined by evaluating the high temperature dynamic behavior, which is mainly reflecting the surrounding oxygen concentration. In atmospheres with varying oxygen concentration or other circumstances which interfere with the DSO evaluation, a reference gas mixture could be used to determine the balance between combustion and thermal conductivity as an indicator of the sensor state. Acknowledgement Part of this research was done within the project “GasMOS” funded by the European Regional Development Fund (ERDF). We want to thank our project partner Schaller automation GmbH & Co. KG for their ongoing support. References [1] G. Korotcenkov and B. K. Cho, Sensors Actuators, B Chem. , vol. 156, no. 2, pp. 527–538, 2011. doi:10.1617/s11527-012-0006-0 [2] M. Fleischer, S. Kornely, T. Weh, J. Frank, and H. Meixner, Sensors Actuators, B Chem. , vol. 69, no. 1, pp. 205–210, 2000. doi:10.1016/S0925-4005(00)00513-X [3] D. E. Williams and K. F. E. Pratt, J. Chem. Soc. - Faraday Trans. , vol. 94, no. 23, pp. 3493–3500, 1998. doi:10.1039/a807644h [4] M. Leidinger, C. Schultealbert, J. Neu, A. Schütze, and T. Sauerwald, Meas. Sci. Technol. , vol. 29, no. 1, 2018. doi:10.1088/1361-6501/aa91da [5] M. Schüler, T. Sauerwald, and A. Schütze, J. Sensors Sens. Syst. , vol. 4, no. 2, pp. 305–311, 2015. doi:10.5194/jsss-4-305-2015 [6] X. Liu, S. Cheng, H. Liu, S. Hu, D. Zhang, and H. Ning, vol. 12, no. 7, pp. 9635–9665, 2012. doi:10.3390/s120709635 Figure 1