Construction of 1D SnO(2)-coated ZnO nanowire heterojunction for their improved n-butylamine sensing performances

One-dimensional (1D) SnO(2)-coated ZnO nanowire (SnO(2)/ZnO NW) N-N heterojunctions were successfully constructed by an effective solvothermal treatment followed with calcination at 400 °C. The obtained samples were characterized by means of XRD, SEM, TEM, Scanning TEM coupled with EDS and XPS analysis, which confirmed that the outer layers of N-type SnO(2) nanoparticles (avg. 4 nm) were uniformly distributed onto our pre-synthesized n-type ZnO nanowire supports (diameter 80~100 nm, length 12~16 μm). Comparisons of the gas sensing performances among pure SnO(2), pure ZnO NW and the as-fabricated SnO(2)/ZnO NW heterojunctions revealed that after modification, SnO(2)/ZnO NW based sensor exhibited remarkably improved response, fast response and recovery speeds, good selectivity and excellent reproducibility to n-butylamine gas, indicating it can be used as promising candidates for high-performance organic amine sensors. The enhanced gas-sensing behavior should be attributed to the unique 1D wire-like morphology of ZnO support, the small size effect of SnO(2) nanoparticles, and the semiconductor depletion layer model induced by the strong interfacial interaction between SnO(2) and ZnO of the heterojunctions. The as-prepared SnO(2)/ZnO NW heterojunctions may also supply other novel applications in the fields like photocatalysis, lithium-ion batteries, waste water purification, and so on.