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Beilstein J. Nanotechnol. 2013, 4, 20–31, doi:10.3762/bjnano.4.3
Figure 1: Schematic representation of PS sensor interface structure. Reproduced with permission from [3]. Copyri...
Figure 2: Estimated hard and soft acidities and basicities based on resistance changes relative to a p-type a...
Figure 3: Response corresponding to decreasing resistance as NH3 contributes electrons to an untreated porous...
Figure 4: Response corresponding to decreasing resistance as NH3 contributes electrons to a CuxO-treated poro...
Figure 5: Response corresponding to decreasing resistance as NH3 contributes electrons to a TiO2 treated n-ty...
Figure 6: Response corresponding to increased resistance as NO2 extracts electrons from a TiO2 treated n-type...
Figure 7: Response corresponding to decreasing resistance as a significant TiO2−xNx fractional nanostructure ...
Figure 8: Comparison of responses to 1–5 and 10 ppm NO for (a) an untreated n-type PS micro/nanostructured in...
Figure 9: Comparison of a metal-oxide (usually SnO2 or WO3) elevated-temperature (150–500 °C) heat-controlled...
Figure 10: (a) Schematic view of apparatus used to generate the micro/nanoporous structure in n-type silicon. ...
Figure 11: (a) Close up side view of hybrid porous silicon film. (b) 10–100 nm SnOx nanoparticle tin-oxide dep...