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Beilstein J. Nanotechnol. 2017, 8, 1205–1217, doi:10.3762/bjnano.8.122
Figure 1: FE-SEM images of NiO nanowires at different magnifications (top), SnO2 nanowires (middle) and ZnO n...
Figure 2: Raman spectrum of NiO nanowires deposited on alumina substrate measured in ambient air at room temp...
Figure 3: Raman spectrum of SnO2 nanowires deposited on alumina substrate measured in ambient air at room tem...
Figure 4: Raman spectrum of ZnO nanowires deposited on alumina substrates measured in ambient air at room tem...
Figure 5: SEM picture of WO3 nanowires on alumina substrate.
Figure 6: Raman spectrum performed on WO3 nanowire deposited on alumina substrate measured in ambient air at ...
Figure 7: SEM images of Nb2O5 nanoflowers at 25k (left) and 75k (right) magnification level.
Figure 8: Raman spectrum of Nb2O5 nanoflowers deposited on alumina substrate measured in ambient air at room ...
Figure 9: Dynamic response of NiO and Nb2O5 sensing devices towards (a) (CO; 50 ppm, NiO (300 °C) and Nb2O5 (...
Figure 10: Sensor response towards 50 ppm of CO (left) and 1 ppm of NO2 (right) as a function of the temperatu...
Figure 11: Calibration curves and power-law fitting for CO (left) and NO2 (right). The relative humidity was k...
Figure 12: Principal component analysis (PCA) score plot for drinking water (blue and green dots) and a soluti...
Figure 13: Content of VOCs over seven days of analysis.
Figure 14: Growth of 1D structures by evaporation–condensation.
Figure 15: Flow chart describing the synthesis process of tungsten oxide nanowires.
Figure 16: Flow chart describing the synthesis process for niobium oxide nanostructures by hydrothermal treatm...
Beilstein J. Nanotechnol. 2014, 5, 927–936, doi:10.3762/bjnano.5.106
Figure 1: SEM images of ZnO nanowires deposited at substrate temperatures of (a) 700 °C and (b) 1070 °C. (c) ...
Figure 2: SEM images of CuO nanowires fabricated at (a) 250 °C and (b) 400 °C. (c) Dependence of the applied ...
Figure 3: (a) Optical image of fabricated planar thermoelectric device based on ZnO and CuO nanowires. (b) SE...
Figure 4: XRD spectra of the fabricated thermoelectric module (top to bottom as labeled).
Figure 5: Raman spectra of the fabricated thermoelectric module for ZnO (red), CuO (green) and alumina substr...
Figure 6: (a) Dependence of the applied temperature difference ΔT and the thermoelectric voltage ΔV as functi...
Figure 7: Schematics of the fabrication process.
Figure 8: Schematic diagram (side view) of the experimental set-up for the measurement of the thermoelectric ...
Beilstein J. Nanotechnol. 2012, 3, 368–377, doi:10.3762/bjnano.3.43
Figure 1: Scanning electron microscopy images of (a) the drop-cast ZnO nanoparticle sensor surface; (b) the p...
Figure 2: Transmission electron microscopy images and size-distribution analyses of ZnO nanocrystals after he...
Figure 3: FTIR spectra of (a) pure ZnO nanowire sensor; (b) dodecanethiol-coated ZnO nanowire sensor; and (c)...
Figure 4: XPS spectra of (a) the sulfur peak of DT-functionalised ZnO NW sensor surface and (b) the amide pea...
Figure 5: TG and DTG of (a) DT-coated and (b) THMA-coated ZnO obtained in air at 5 °C·min−1.
Figure 6: Dynamic response of the same ZnO nanowire sensor, (a) before and after THMA functionalization and (...
Figure 7: Dynamic response of the same ZnO nanowire sensor, (a) before and after coating with ZnO nanoparticl...