Abstract
The development of WO(3)-based gas sensors for analysis of acetone in exhaled breath is significant for noninvasive diagnosis of diabetes. A series of Fe-doped hexagonal and monoclinic WO(3) phase-junction (Fe-h/m-WO(3)) sensors were synthesized by the hydrothermal calcination method, and the influences of operating temperature and light irradiation on the response were studied. Under light emitting diode (LED) illumination, Fe-h/m-WO(3) exhibited higher responses to acetone than those of the undoped WO(3)-based sensors at an operating temperature of 260 °C with 90% relative humidity, and good linearity between response and acetone concentration (0.5 to 2.5 ppm) was achieved under the 90% relative humidity condition. Meanwhile, the optimal Fe-h/m-WO(3) sensor exhibited high selectivity and stability for a duration of three months. The excellent sensing performance of Fe-h/m-WO(3) was attributed to the formation of phase-junction and Fe doping, and these were beneficial for the separation of photon-generated carriers and oxygen adsorption on the WO(3) surface, promoting the generation of superoxide radicals, which was demonstrated by electron paramagnetic resonance and photocurrent tests. Additionally, the Fe-doped WO(3) phase-junction sample also showed good photocatalytic performance for rhodamine B degradation. This study may provide some insights into rational design of new types of gas sensors and offer an alternative for noninvasive diagnosis of diabetes.