Co2 sensing characteristics of a La2O3/SnO2 stacked structure with micromachined hotplates

Abstract

Demand for the detection of carbon dioxide (CO2) is increasing in various fields, including air-quality monitoring, healthcare, and agriculture. On the other hand, smart gas sensors, in which micromachined gas sensors are integrated with driving circuits, are desirable toward the development of the society of the internet of things. In this study, micromachined hotplate-based CO2 sensors were fabricated and their characteristics were investigated. The sensors have La2O3/SnO2 stacked layers as a sensing material and Pt interdigitated electrodes. A CO2 response of 2.9 for a CO2 concentration of 1000 ppm was obtained at 350◦C with low power consumption (approximately 17 mW). A relatively large response was obtained compared with previous studies even though a compact sputtered-SnO2 film was used. This high response was speculated to be due to a significant contribution of the resistance component near the electrode. Furthermore, CO2 sensing was successfully performed in the CO2 range of 200–4000 ppm with at least 200-ppm resolution.