关键词: ZnO基敏感材料, 金属掺杂与二维材料复合, Cu-Zn双金属活性位点, 热力学反应与界面性质, 传感机制, 密度泛函理论计算

Of numerous environmental problems, the air pollution caused by toxic nitrogen dioxide has become more and more serious. Its timing detection is of utmost importance but challenging. It is known that NO₂ sensors fabricated by zinc oxide-derived materials suffer some issues. And thus synthetic strategies such as doping and combining have been developed to improve sensitive performance and modify operation condition. However, the relevant sensing reaction mechanism still remains unclear; moreover, the experimentally structural characterizations on sensitive materials (SMs) and reaction intermediates are rather difficult at the atomic level, which turn much worse for the doped and combined SMs. In the work, density functional theory calculations have been exploited to examine copper-doped zinc oxide (marked as ZOC) and its composites ZOC/CN and ZOC/Gr. CN and Gr are short for 2D materials, graphitic carbon nitride (g-C₃N₄) and graphene, respectively. The local structures have been accessible for these SMs and their intermediates along the reaction pathway. It is shown that ZOC bears the Cu-Zn heterobimetallic adsorption active sites, which hold NO₂ via Cu/Zn-O dative bonds. The introduction of copper increases metal contribution to high-lying occupied molecular orbitals (MOs). Major NO₂→ZOC donation and minor back-donation interactions have been recognized by charge decomposition analyses in terms of fragment MOs. Consequently, its adsorption free energy towards NO₂ is strengthened by 0.27 eV relative to pristine ZnO. These well interpret the experimental findings that the copper-doped zinc oxide has much faster response time. Further combination with g-C₃N₄ enhances the NO₂-sensing performance, which turns out to be the best SM candidate. Exemplarily, ZOC/CN shows the most negative NO₂ adsorption energy (–0.31 eV), very small uphill energy for the rate-determining step (0.27 eV) and modest formation energy of nitrate (–1.06 eV). With these, the SM not only responses NO₂ rapidly but also desorbs nitrate at mild experimental condition. In brief, the theoretical study allows to deeply understand synthetic strategies that can improve sensing performance, and helps to search out novel sensitive materials.

Key words: ZnO-based sensitive material, metal-doping and 2D material combination, Cu-Zn heterobimetallic active sites, thermodynamics and interfacial property, sensing mechanism, DFT calculations