Your search keyword '"Bernhard Schaffer"' showing total 2 results

1. Monochromated, spatially resolved electron energy-loss spectroscopic measurements of gold nanoparticles in the plasmon range

Author

Gerald Kothleitner, Ferdinand Hofer, Werner Grogger, Katharina Riegler, and Bernhard Schaffer

Subjects

Materials science, Resolution (electron density), Surface plasmon, Analytical chemistry, Physics::Optics, General Physics and Astronomy, Nanoparticle, Cell Biology, Electron, Molecular physics, Structural Biology, Colloidal gold, Scanning transmission electron microscopy, Energy filtered transmission electron microscopy, General Materials Science, Plasmon

Abstract

Gold nanoparticles show optical properties different from bulk material due to resonance phenomena which depend on local structure and geometry. Electron energy-loss spectrometry (EELS) in scanning transmission electron microscopy (STEM) allows the spatially resolved measurement of these properties at a resolution of few nanometers. In this work, the first monochromated measurements of gold nanoparticles (spheres, rods and triangles) are presented. Due to the improved energy resolution of about 0.2 eV, surface plasmon excitations at energies below 1 eV could be accurately measured from raw experimental data.

Published

2009

2. Čerenkov losses: A limit for bandgap determination and Kramers–Kronig analysis

Author

Michael Stöger-Pollach, Bernhard Schaffer, Henny W. Zandbergen, Sorin Lazar, H. Franco, Werner Grogger, and Peter Schattschneider

Subjects

Diffraction, Physics, Kramers–Kronig relations, Photon, Band gap, business.industry, Electronvolt, General Physics and Astronomy, Cell Biology, law.invention, Condensed Matter::Materials Science, Optics, Semiconductor, Structural Biology, law, General Materials Science, business, Cherenkov radiation, Monochromator

Abstract

Measuring low energy losses in semiconductors and insulators with high spatial resolution becomes attractive with the increasing availability of modern transmission electron microscopes (TEMs) equipped with monochromators, Cs correctors and energy filters. In this paper, we demonstrate that Cerenkov losses pose a limit for the interpretation of low energy loss spectra (EELS) in terms of interband transistions and bandgap determination for many materials. If the velocity of a charged particle in a medium exceeds the velocity of light, photons are emitted leading to a corresponding energy loss of a few electronvolt. Since these losses are strong for energies below the onset of interband transitions, they change the apparent loss function of semiconductors and insulators, with the risk of erroneous interpretation of spectra. We measured low energy losses of Si and GaAs with a monochromated TEM demonstrating the effect of sample thickness on Cerenkov losses. Angle resolved EELS and energy filtered diffraction patterns (taken without a monochromator) show the extremely narrow angular distribution of Cerenkov losses. The latter experiment provides a method that allows to decide whether Cerenkov radiation masks the very low loss signal in EELS.

Published

2006