Enhancing Methane Gas Sensing through Defect Engineering in Ag-Ru Co-doped ZnO Nanorods.
Xun LiHui HuTian TanMengjing SunYuwen BaoZhong-Bing HuangSohail MuhammadXiaohong XiaYun GaoPublished in: ACS applied materials & interfaces (2024)
Detection of leaks of flammable methane (CH 4 ) gas in a timely manner can mitigate health, safety, and environmental risks. Zinc oxide (ZnO), a polar semiconductor with controllable surface defects, is a promising material for gas sensing. In this study, Ag-Ru co-doped into self-assembled ZnO nanorod arrays (ZnO NRs) was prepared by a one-step hydrothermal method. The Ag-Ru co-doped sample shows a good hydrophobic property as a result of its particular microstructure, which results in high humidity resistance. In addition, oxygen vacancy density significantly increased after Ag-Ru co-doping. Density functional theory (DFT) calculations revealed an exceptionally high charge density accumulated at the Ru sites and the formation of a localized strong electric field, which provides additional energy for the CH 4 reaction with • O 2 - at the surface at room temperature. Optimized AgRu 0.025 -ZnO demonstrated an outstanding CH 4 sensing performance, with a limit of detection (LOD) as low as 2.24 ppm under free-heat and free-light conditions. These findings suggest that introducing defects into the ZnO lattice, such as oxygen vacancies and localized ions, offers a promising approach to improving the gas sensing performance.
Keyphrases
- room temperature
- quantum dots
- energy transfer
- density functional theory
- ionic liquid
- visible light
- highly efficient
- sensitive detection
- molecular dynamics
- anaerobic digestion
- healthcare
- public health
- loop mediated isothermal amplification
- single cell
- mental health
- human health
- social media
- molecular dynamics simulations
- climate change
- health information
- risk assessment
- crystal structure
- reduced graphene oxide
- electron transfer
- soft tissue
- sewage sludge