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Beilstein J. Nanotechnol. 2016, 7, 1507–1518, doi:10.3762/bjnano.7.144
Figure 1: SEM micrograph of as-grown indium oxide nano-octahedra.
Figure 2: XRD patterns of the pure In2O3 octahedra (top) and a commercially available In2O3 powder (bottom). ...
Figure 3: Successive response and recovery cycles during exposure to increasing concentrations of nitrogen di...
Figure 4: Successive response and recovery cycles during exposure to increasing concentrations of nitrogen di...
Figure 5: Resistance change of an indium oxide sensor suddenly exposed to UV light (the UV diode is switched ...
Figure 6: Response and recovery cycles of an indium oxide sensor exposed to different concentrations of nitro...
Figure 7: Successive recovery, response (nitrogen dioxide, 500 ppb) and recovery cycles of an indium oxide se...
Figure 8: The instantaneous oxidation and reduction rates are defined as Roxi = [S(t + 1) − S(t)]/Δt and Rred...
Figure 9: Indium oxide sensor response under pulsed UV irradiation. The sensor was operated at room temperatu...
Figure 10: Indium oxide sensor response under pulsed UV irradiation. The sensor was operated at 50 °C. Every p...
Figure 11: Indium oxide sensor response under pulsed UV irradiation. The sensor was operated at 100 °C. Every ...
Figure 12: Analysis of the response of an indium oxide sensor operated at 50 °C under pulsing UV light. The up...
Figure 13: Calibration curves for the detection of nitrogen dioxide with an indium oxide sensor operated at th...
Figure 14: Sensor chamber used during the experiments, which can house up to six sensors (left). The chamber i...