Scanning photo-induced impedance microscopy (SPIM) is a method to detect a local impedance change on the sensor surface [1]. In this study, tin dioxide (SnO₂) film is deposited on sensor surface by vacuum evaporation [2] as a sensing material to detect ethanol [3]. The impedance change of the SnO₂ film in response to ethanol is read out in the form of an ac photocurrent signal, generated by a focused laser beam modulated at 3.5 kHz. A schematic of the fabricated structure is shown in Fig. 1a.
The response of the fabricated sensor to ethanol vapor was investigated. Fig. 1b shows the photocurrent-bias voltage characteristics, which were measured before, during and after exposing the sensor to ethanol vapor. As can be seen, the photocurrent at low bias voltages increased in response to the ethanol vapor, which suggests lowering of the impedance of the SnO₂ layer. In addition, a spatially resolved measurement of the gas concentration on the sensor is possible (see Fig. 1c) due to the light-addressability. This gas-sensitive SPIM is expected to have potential applications such as breath analysis, food security, process control and air quality monitoring.