Simple self-assembly of 3D laminated CuO/SnO2 hybrid for the detection of triethylamine

3D CuO/SnO2 was composed of 2D lamellae consisting of ordered nanoparticles. Its laminated structure and heterojunction endow CuO/SnO2-based sensor an enhanced sensing properties, i.e., an impressive sensitivity and selectivity to TEA in gas phase. [Display omitted] Tin dioxide is important gas sensor material and has wide applications in the detection of toxic gases and volatile organic compounds. Here, we synthesized a 3D laminated structural CuO/SnO2 material possessing p-n heterostructures. The morphology and structure were characterized by XRD, SEM, TEM and XPS techniques and the sensing properties were investigated for the detection of triethylamine (TEA). The results indicate that 3D laminated CuO/SnO2 material, assembled by lamellae consisting of ordered nanoparticles, exhibit an enhanced sensing performance compared with SnO2, and notably, CuO/SnO2 with size less than 1 μm has obvious high selectivity in the detection of 100 ppm TEA. Particularly, it has a high response and stability to 1 and 5 ppm TEA (S is 8 and 33), and that is higher than SnO2 material, suggesting 3D laminated CuO/SnO2 is an effective candidate material served as sensor platform to detect low-concentration amines.