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2 article(s) from Herr, Ulrich

Near-field effects and energy transfer in hybrid metal-oxide nanostructures

Ulrich Herr,
Balati Kuerbanjiang,
Cahit Benel,
Giorgos Papageorgiou,
Manuel Goncalves,
Johannes Boneberg,
Paul Leiderer,
Paul Ziemann,
Peter Marek and
Horst Hahn

Beilstein J. Nanotechnol. 2013, 4, 306–317, doi:10.3762/bjnano.4.34

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Figure 1: CVR chamber consisting of precursor sources, reaction zone and thermophoretic powder-collection sys...

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Figure 2: X-ray diffraction patterns (Cu Kα radiation) from the TiO₂:Eu nanophosphors produced by the CVR met...

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Figure 3: Normalized emission spectra of Eu³⁺ in TiO₂ under excitation at 330 or 390 nm.

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Figure 4: Excitation spectrum of TiO₂:Eu nanoparticles detected at 617 nm emission.

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Figure 5: Decay of the TiO₂:Eu emission intensity with time for excitation at 330 nm.

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Figure 6: Decay of the TiO₂:Eu emission intensity at 617 nm with time for excitation at 460 nm.

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Figure 7: STEM image of TiO₂:Eu nanoparticles coated with a shell of 3 nm Al₂O₃ and TiO₂.

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Figure 8: High-resolution TEM image of TiO₂ nanoparticles coated with Al₂O₃ showing that the Al₂O₃ coating is...

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Figure 9: SEM image of Ag nanoantennas from the nanosphere lithography process (using colloid spheres with 3 ...

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Figure 10: Confocal microscopy images of the Ag nano-antenna structures (produced using 3 μm diameter colloid ...

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Figure 11: Calculated field-enhancement factor (normalized to the amplitude E₀ of the incident light) for bowt...

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Figure 12: Field enhancement ratio (scale goes from 0 to 90) for Ag bow-tie nano-antennas with tip-to-edge len...

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Figure 13: Dependence of the field enhancement in the centre of the gap of a bowtie antenna structure on the i...

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Figure 14: Field enhancement ratio for an array of Ag nanoantenna structures with tip-to-edge length of 370 nm...

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Figure 15: SEM image of spin coated TiO₂:Eu layer on Ag nanoantenna structures.

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Figure 16: (a) AFM image of the spin coated TiO₂:Eu layer. The antenna structure is still visible in this regi...

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Figure 17: Fluorescent intensity obtained by confocal microscopy of spin-coated nanoantenna structures under e...

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Figure 18: Emission spectrum of VTLUNP organic pigment under excitation with 532 nm radiation.

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Figure 19: Excitation spectrum of VTLUNP organic pigment for emission at 614 nm.

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Figure 20: (a) AFM image of Ag nanoantennas spin coated with VTLUNP (b) AFM height profiles along the lines 1 ...

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Figure 21: Representative scattering (a, c) and fluorescence (b, d) images of the samples spin coated with VTL...

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Figure 22: Representative fluorescence images (recorded at 614 nm) of samples without SiO_x layer (a, b) and sa...

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Full Research Paper

Published 14 May 2013

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Effect of large mechanical stress on the magnetic properties of embedded Fe nanoparticles

Srinivasa Saranu,
Sören Selve,
Ute Kaiser,
Luyang Han,
Ulf Wiedwald,
Paul Ziemann and
Ulrich Herr

Beilstein J. Nanotechnol. 2011, 2, 268–275, doi:10.3762/bjnano.2.31

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Figure 1: Scanning electron micrograph of Fe nanoparticles deposited on Si. The average particle size observe...

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Figure 2: Transmission electron microscope image of Fe nanoparticles (dark contrast) coated with a thin SiO_x ...

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Figure 3: Electron diffraction pattern of the Fe nanoparticles. The Miller indices of the respective lattice ...

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Figure 4: X-ray diffraction patterns (Cu Kα radiation) of Fe nanoparticles embedded in a Cu film on a Ta subs...

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Figure 5: In-plane hysteresis curves of the embedded Fe nanoparticles measured at 10 K in as-prepared state (...

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Figure 6: In-plane hysteresis curves of the embedded Fe nanoparticles after loading of the Ta substrate with ...

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Figure 7: ZFC (circles) and FC (squares) magnetization curves of the Fe nanoparticles embedded in Cu film in ...

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Full Research Paper

Published 01 Jun 2011

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