| Literature DB >> 18793491 |
C Kisielowski1, B Freitag, M Bischoff, H van Lin, S Lazar, G Knippels, P Tiemeijer, M van der Stam, S von Harrach, M Stekelenburg, M Haider, S Uhlemann, H Müller, P Hartel, B Kabius, D Miller, I Petrov, E A Olson, T Donchev, E A Kenik, A R Lupini, J Bentley, S J Pennycook, I M Anderson, A M Minor, A K Schmid, T Duden, V Radmilovic, Q M Ramasse, M Watanabe, R Erni, E A Stach, P Denes, U Dahmen.
Abstract
The ability of electron microscopes to analyze all the atoms in individual nanostructures is limited by lens aberrations. However, recent advances in aberration-correcting electron optics have led to greatly enhanced instrument performance and new techniques of electron microscopy. The development of an ultrastable electron microscope with aberration-correcting optics and a monochromated high-brightness source has significantly improved instrument resolution and contrast. In the present work, we report information transfer beyond 50 pm and show images of single gold atoms with a signal-to-noise ratio as large as 10. The instrument's new capabilities were exploited to detect a buried Sigma3 {112} grain boundary and observe the dynamic arrangements of single atoms and atom pairs with sub-angstrom resolution. These results mark an important step toward meeting the challenge of determining the three-dimensional atomic-scale structure of nanomaterials.Year: 2008 PMID: 18793491 DOI: 10.1017/S1431927608080902
Source DB: PubMed Journal: Microsc Microanal ISSN: 1431-9276 Impact factor: 4.127