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Beilstein J. Nanotechnol. 2019, 10, 1380–1390, doi:10.3762/bjnano.10.136
Figure 1: Scheme of nanowire synthesis (a), SEM image of SnO2 nanowires after synthesis (b), SEM image of a s...
Figure 2: TEM image of blank tin dioxide nanopowder after annealing.
Figure 3: Nanowire with electrical contacts.
Figure 4: Experimental diffractograms of SnO2 nanowire (blue) and SnO2 nanopowder (red).
Figure 5: Photoelectron survey spectra for tin dioxide nanowires and powder samples obtained at an excitation...
Figure 6: XPS spectra of (a) SnO2 powder, Sn 3d5/2; (b) SnO2 powder, O 1s; (c) SnO2 nanowires, Sn 3d5/2; (d) ...
Figure 7: XANES Sn M4,5 spectra of SnO2 wire-like crystals (top) [37,38], SnO2 powder (middle) and sintered SnO2 lum...
Figure 8: XANES O K spectra of SnO2 wire-like crystals (top) [37,38], SnO2 powder (middle) and sintered SnO2 lump re...
Figure 9: Response of nanowire and nanopowder sensors towards different concentrations of ammonia.
Figure 10: Calibration curves of the nanowire (NW) and sol–gel (nanopowder) sensors.
Figure 11: Response of two sensors based on sol–gel technology and on an individual nanowire (NW) as a functio...