Nanoscale layer of a minimized defect area of graphene and hexagonal boron nitride on copper for excellent anti-corrosion activity

In this work, we synthesized a monolayer of graphene and hexagonal boron nitride (hBN) using chemical vapor deposition. The physicochemical and electrochemical properties of the materials were evaluated to determine their morphology. High-purity materials and their atomic-scale coating on copper (Cu) foil were employed to prevent fast degradation rate. The hexagonal two-dimensional (2D) atomic structures of the as-prepared materials were assessed to derive their best anti-corrosion behavior. The material prepared under optimized conditions included edge-defect-free graphene nanosheets (similar to 0.0034 mu m(2)) and hBN (similar to 0.0038 mu m(2)) per unit area of 1 mu m(2). The coating of each material on the Cu surface significantly reduced the corrosion rate, which was similar to 2.44 x 10(-2)/year and 6.57 x 10(-3)/year for graphene/Cu and hBN/Cu, respectively. Importantly, the corrosion rate of Cu was approximately 3-fold lower after coating with hBN relative to that of graphene/Cu. This approach suggests that the surface coating of Cu using cost-effective, eco-friendly, and the most abundant materials in nature is of interest for developing marine anti-corrosion micro-electronic devices and achieving surface modification of pure metals in industrial applications.

Automated summary

In this study, a monolayer of graphene and hexagonal boron nitride (hBN) was synthesized using chemical vapor deposition. The materials were evaluated for their physicochemical and electrochemical properties, and high-purity materials were used to prevent degradation. The optimized preparation conditions resulted in graphene nanosheets and hBN with edge-defect-free structures, and the coating significantly reduced the corrosion rate of copper.