Atomic Ru Species Driven SnO<sub>2</sub>-Based Sensor for Highly Sensitive and Selective Detection of H<sub>2</sub>S in the ppb-Level
Mingjia Zheng, Youde Cheng, Xiuli Zhang, Haonan Liu, Haiyan Xu, Xiangsu Dai, Guolong Shi, Yuan Rao, Lichuan Gu, Ming‐Sheng Wang, Chao Li, Ke Li
Abstract
Timely and accurate detection of H 2 S is crucial for preventing serious health issues in both humans and livestock upon exposure. However, metal-oxide-based H 2 S sensors often suffer from mediocre sensitivity, poor selectivity, or long response/recovery time. Here, an atomic Ru species-driven SnO 2 -based sensor is fabricated to realize highly sensitive and selective detection of H 2 S at the parts per billion level as low as 100 ppb. The sensor shows a high sensing response ( R air / R gas = 310.1) and an ultrafast response time (less than 1 s) to 20 ppm H 2 S at an operating temperature of 160 °C. Operando SR-FTIR spectroscopic characterizations and DFT calculations prove that the superior sensing properties can be mainly attributed to the driven effect of atomic Ru species on the formation of surface-adsorbed oxygen species on the surface of SnO 2, which provides more active sites and enhances the sensing performance of SnO 2 for H 2 S. Furthermore, a lab-made wireless portable H 2 S monitoring system is developed to rapidly detect the H 2 S for early warning, suggesting the potential application of the fabricated H 2 S sensor and monitoring system. This work provides a novel approach for fabricating a highly sensitive and selective gas sensor driven by atomic metal species loaded on metal-oxide semiconductors.