Oxygen-Plasma Defect Engineering of Epitaxial Graphene on 4H-SiC for Enhanced NO2 Sensing.
Xuan Thang Trinh, Anh Tuan Nguyen, Tham Thi Hong Nguyen, Tuan Quoc Dang, Hoai Duy Tran, Phuong Thanh Nguyen, Tuan Minh Dao, Ly Huu Truong, Cuong Quoc Le, Trung T Pham, Vu Nguyen-Si, Huynh Thien Ngo
Abstract
Open AccessDeveloping sensitive, low-power, and manufacturable NO2 gas sensors is crucial for environmental and health monitoring. Epitaxial graphene on 4H-silicon carbide (Graphene@4H-SiC) is an ideal, device-ready platform, but its intrinsically inert surface limits its sensing performance. Here, we present a complete workflow that combines a scalable oxygen plasma treatment for defect engineering with the fabrication of a fully operational chemiresistive sensor device. The optimized sensor, treated at 150 W, demonstrates a nearly 8-fold response enhancement to NO2 compared to its pristine counterpart. It exhibits excellent recovery and sensitive detection down to 10 ppm at a low operating temperature of 70 °C. Crucially, a synergistic approach combining extensive experimental characterization with first-principles simulations reveals the underlying mechanism. Density functional theory calculations identify carbon vacancies as overwhelmingly potent adsorption sites, with a binding energy (-7.97 eV) and charge transfer far exceeding that of pristine graphene or common oxygen functional groups. The excellent correlation between the experimental performance peak and the theoretical superiority of vacancy defects provides a validated understanding of the enhancement. This work bridges the critical gap between atomic-scale theory and practical device performance, establishing a rational design pathway for high-performance graphene sensors.