One-Step Electrospun WO<sub>3</sub>/CuO p–n Heterojunction Nanocomposites for Ultrasensitive and Rapid H<sub>2</sub>S Detection
Changkun Qiu, Liang Zhu, Qingrun Li, Haozhi Wang, Fei An, Shiqiang Wang, Chao Fan, Dongzhi Zhang, Zhe Yang
Abstract
Hydrogen sulfide (H 2 S), a critical industrial gas, exhibits high toxicity, flammability, and strong corrosiveness, posing severe health risks at elevated concentrations. Consequently, developing highly sensitive and rapid-response detection methods is imperative. In this study, WO 3 /CuO nanocomposites were synthesized via a one-step electrospinning technique, enabling the fabrication of high-performance H 2 S gas sensors. The gas-sensing properties of WO 3 /CuO nanocomposites for H 2 S detection were systematically investigated. The composite sensor demonstrated optimal performance at 150 °C, with a CuO mass fraction of 5 wt % yielding the highest H 2 S response. For 5 ppm of H 2 S in air, the WO 3 /CuO sensor exhibited a response value of 68.43%, with a rapid response time of 24 s and recovery time of 78 s at 150 °C. The enhanced H 2 S sensing performance is attributed to the formation of p–n heterojunctions at the WO 3 /CuO interface, which improves long-term stability. This mechanism was corroborated by in situ TEM and XRD analyses. Furthermore, the unique interaction between CuO and H 2 S enhances low-concentration detection sensitivity. First-principles calculations revealed that the performance improvement arises from CuO sensitization effects and heterojunction formation. These findings provide novel insights and a theoretical foundation for advancing high-reliability gas sensor technologies.