Speakers: Christian Colliex (Laboratoire de Physique des Solides (UMR CNRS 8502), Bldg. 510, Université Paris Sud XI, 91405 Orsay (France))
Place: Na Slovance, main lecture hall
Presented in English
Organisers:
Department of Condensed Matter Theory; Section of Condensed Matter Physics
EELS (Electron Energy Loss Spectroscopy) now constitutes a major component in any new electron microscope, in particular for the characterization of solid specimens at sub nanometer level. It is commonly used for elemental mapping, in which case atomic resolution and single atom sensitivity have been demonstrated, and it has found wide areas of applications in many scientific domains. Recent progress in instrumentation (spectrometers, monochromators, detectors) and in methodology (data processing) now provide access to increased performance, to upgraded accuracy and precision and also to unconventional domains lying out of the main stream. Aberration corrected STEM instruments delivering a sub-angström incident electron beam probe on the specimen surface, have proved their capacity to generate atomic-scale maps of the interface chemistry in perovskite-based systems for spintronic applications. Some examples in this domain will be shown and discussed. The abruptness of the interfaces at the atomic-scale is demonstrated, along with some initial analysis of the oxidation states for the metal ions as it can be deduced from the spatial variations of the fine EELS structures on characteristic core-edges (ELNES). In the low energy-loss part of an EELS spectrum, new routes are now opened to disentangle the local electronic response of the material in terms of band structure (band gap, interband transitions, excitons) from the long-range response of the neighbouring architecture, encompassing the electromagnetic fields generated by surface and interface plasmons. In particular, when applied to individual metallic nanoparticles, it has been demonstrated that the measured EELS signal is closely related to the electromagnetic modes density of states (EMDOS) defined by the shapes and dimensions of the investigated nanostructures, thus opening extended access to the comprehension of plasmon physics and to the conception of new structures and devices of interest in nanophotonics.
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