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Beilstein J. Nanotechnol. 2017, 8, 108–122, doi:10.3762/bjnano.8.12
Figure 1: Schematics illustrating the beneficial action of n–n heterojunctions for the sensitization of the g...
Figure 2: Comparison between XRD patterns of a) SnO2 and 90 mol % SnO2/10 mol % TiO2; b) TiO2 and 90 mol % TiO...
Figure 3: Mössbauer transmission spectra of: a) SnO2; b) 90 mol % SnO2/10 mol % TiO2; c) 90 mol % TiO2/10 mol...
Figure 4: Dynamic changes in the electrical resistance, R, of: a) 90 mol % SnO2/10 mol % TiO2 (H2 concentrati...
Figure 5: Dynamic changes in the electrical resistance, R, of: a) 90 mol % SnO2/10 mol % TiO2; b) 10 mol % SnO...
Figure 6: Dynamic changes in the electrical resistance, R, of: a) 90 mol % SnO2/10 mol % TiO2; b) 10 mol % SnO...
Figure 7: Temperature dependence of the electrical resistance in air, R0, compared with that upon interaction...
Figure 8: a) Impedance spectra of 90 mol % SnO2/10 mol % TiO2 and 90 mol % TiO2/10 mol % SnO2 at 400 °C along...
Figure 9: Log–log plot of the inverse of electrical resistance vs the hydrogen partial pressure for: a) 90 mo...
Beilstein J. Nanotechnol. 2016, 7, 1718–1726, doi:10.3762/bjnano.7.164
Figure 1: Schematic view of gas sensor measuring system.
Figure 2: XRD patterns of TiO2-based sensors: a) T30 – TiO2 thin layer, flower-like TiO2 (NS0) and TiO2/SnO2 ...
Figure 3: Top-views (a,c–g) and side-views (b,h) of flower-like TiO2 nanostructures prepared via chemical oxi...
Figure 4: Gas sensing characteristics for the T30 sensor: dynamic changes in the electrical resistance upon e...
Figure 5: Response tres and recovery trec times of the T30 sensor calculated for NOx and CO(CH3)2 at differen...
Figure 6: Radar plots of the response, S, of TiO2-based nanostructured sensors: (a) T30, (b) NS0 and (c) NS1 ...
Figure 7: Comparison of the response of the sensors to various gases.