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Beilstein J. Nanotechnol. 2013, 4, 306–317, doi:10.3762/bjnano.4.34
Figure 1: CVR chamber consisting of precursor sources, reaction zone and thermophoretic powder-collection sys...
Figure 2: X-ray diffraction patterns (Cu Kα radiation) from the TiO2:Eu nanophosphors produced by the CVR met...
Figure 3: Normalized emission spectra of Eu3+ in TiO2 under excitation at 330 or 390 nm.
Figure 4: Excitation spectrum of TiO2:Eu nanoparticles detected at 617 nm emission.
Figure 5: Decay of the TiO2:Eu emission intensity with time for excitation at 330 nm.
Figure 6: Decay of the TiO2:Eu emission intensity at 617 nm with time for excitation at 460 nm.
Figure 7: STEM image of TiO2:Eu nanoparticles coated with a shell of 3 nm Al2O3 and TiO2.
Figure 8: High-resolution TEM image of TiO2 nanoparticles coated with Al2O3 showing that the Al2O3 coating is...
Figure 9: SEM image of Ag nanoantennas from the nanosphere lithography process (using colloid spheres with 3 ...
Figure 10: Confocal microscopy images of the Ag nano-antenna structures (produced using 3 μm diameter colloid ...
Figure 11: Calculated field-enhancement factor (normalized to the amplitude E0 of the incident light) for bowt...
Figure 12: Field enhancement ratio (scale goes from 0 to 90) for Ag bow-tie nano-antennas with tip-to-edge len...
Figure 13: Dependence of the field enhancement in the centre of the gap of a bowtie antenna structure on the i...
Figure 14: Field enhancement ratio for an array of Ag nanoantenna structures with tip-to-edge length of 370 nm...
Figure 15: SEM image of spin coated TiO2:Eu layer on Ag nanoantenna structures.
Figure 16: (a) AFM image of the spin coated TiO2:Eu layer. The antenna structure is still visible in this regi...
Figure 17: Fluorescent intensity obtained by confocal microscopy of spin-coated nanoantenna structures under e...
Figure 18: Emission spectrum of VTLUNP organic pigment under excitation with 532 nm radiation.
Figure 19: Excitation spectrum of VTLUNP organic pigment for emission at 614 nm.
Figure 20: (a) AFM image of Ag nanoantennas spin coated with VTLUNP (b) AFM height profiles along the lines 1 ...
Figure 21: Representative scattering (a, c) and fluorescence (b, d) images of the samples spin coated with VTL...
Figure 22: Representative fluorescence images (recorded at 614 nm) of samples without SiOx layer (a, b) and sa...
Beilstein J. Nanotechnol. 2011, 2, 268–275, doi:10.3762/bjnano.2.31
Figure 1: Scanning electron micrograph of Fe nanoparticles deposited on Si. The average particle size observe...
Figure 2: Transmission electron microscope image of Fe nanoparticles (dark contrast) coated with a thin SiOx ...
Figure 3: Electron diffraction pattern of the Fe nanoparticles. The Miller indices of the respective lattice ...
Figure 4: X-ray diffraction patterns (Cu Kα radiation) of Fe nanoparticles embedded in a Cu film on a Ta subs...
Figure 5: In-plane hysteresis curves of the embedded Fe nanoparticles measured at 10 K in as-prepared state (...
Figure 6: In-plane hysteresis curves of the embedded Fe nanoparticles after loading of the Ta substrate with ...
Figure 7: ZFC (circles) and FC (squares) magnetization curves of the Fe nanoparticles embedded in Cu film in ...