TiO2/Ti1-xSnxO2 heterojunction nanowires: characterization, formation, and gas sensing performance

Tetragonal rutile TiO2/Ti1-xSnxO2 heterojunction nanowires were successfully fabricated through carbothermal reaction with hydrogen gas at 1050 degrees C. These heterojunction nanowires partially formed TiO2/Ti1-xSnxO2 superlattice structures and SnO2 nanocrystals epitaxially grew on the TiO2 nanowire surfaces. Based on the evaluations of Gibbs free energy, all reaction processes were governed by spontaneous reactions with vapor-solid-liquid (VLS). The nanowires exhibited many defect states, such as dislocations, stacking faults, and vacancies, revealed by high-resolution transmission microscopy (HRTEM) and the cathodoluminescence spectrum. The Raman spectrum revealed obvious redshift and asymmetric broadening effects, especially in the position of A(1g) (604 cm(-1)) and E-g (427 cm(-1)) modes when compared with a previous study (J. M. Wu et al., J. Cryst. Growth, 2005, 281, 384.). The size-induced phonon confinement effect and the presence of dislocations with internal strain in the vicinity of the nanowire surfaces led to a downshift and broadening of the first order Raman line. The results are consistent with our observations from the HRTEM images. Operating temperatures of similar to 160 degrees C with a gas sensitivity of similar to 350% were achieved when detecting an ethanol concentration of similar to 300 ppm. The material characterizations and formation mechanism are investigated in detail.