Ultrasensitive and Highly Selective Gas Sensors Based on Electrospun SnO2 Nanofibers Modified by Pd Loading

Abstract This work presents a new route to suppress grain growth and tune the sensitivity and selectivity of nanocrystalline SnO 2 fibers. Unloaded and Pd‐loaded SnO 2 nanofiber mats are synthesized by electrospinning followed by hot‐pressing at 80 °C and calcination at 450 or 600 °C. The chemical composition and microstructure evolution as a function of Pd‐loading and calcination temperature are examined using EDS, XPS, XRD, SEM, and HRTEM. Highly porous fibrillar morphology with nanocrystalline fibers comprising SnO 2 crystallites decorated with tiny PdO crystallites is observed. The grain size of the SnO 2 crystallites in the layers that are calcined at 600 °C decreases with increasing Pd concentration from about 15 nm in the unloaded specimen to about 7 nm in the 40 mol% Pd‐loaded specimen, indicating that Pd‐loading could effectively suppress the SnO 2 grain growth during the calcination step. The Pd‐loaded SnO 2 sensors have 4 orders of magnitude higher resistivity and exhibit significantly enhanced sensitivity to H 2 and lower sensitivity to NO 2 compared to their unloaded counterparts. These observations are attributed to enhanced electron depletion at the surface of the PdO‐decorated SnO 2 crystallites and catalytic effect of PdO in promoting the oxidation of H 2 into H 2 O. These phenomena appear to have a much larger effect on the sensitivity of the Pd‐loaded sensors than the reduction in grain size.