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Quantitative HREM: Reliable Structure Determination of Grain Boundaries in SrTiO3

Published online by Cambridge University Press:  02 July 2020

Thomas Gemming*
Affiliation:
Institute of Solid State and Materials Research Dresden (IFW)Postfach 270116, D-01171, Dresden, Germany
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Abstract

High resolution transmission electron microscopy (HREM) is an excellent experimental method to image grain boundary structures with atomic resolution. The advantage of the method is the short exposure time of only about one second that is needed to record an image. Other methods like Z-contrast imaging require much longer exposure times and are therefore much more prone to specimen drift during recording. However there is the remaining difficulty to HREM that the evaluation of experimental images is not straightforward and a thorough analysis of the images is necessary in order to deduce quantitative information with small error bars of only a few pm (10-15m). A second inherent difficulty common to all atomic resolution imaging techniques is that the information is retrieved from a very small area of a specimen. The question arising from that is: can we nevertheless be sure to obtain a representative answer to a “real world” material science problem? A positive answer to this question is given by the investigations presented here.

Type
Quantitative Transmission Electron Microscopy of Interfaces (Organized by M. Rüehle, Y. Zhu and U. Dahmen)
Copyright
Copyright © Microscopy Society of America 2001

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References

References:

1)Kienzle, O., PhD-Thesis, MPI für Metallforschung, Germany (1998)Google Scholar
2) Wako-Bussan Ltd.Google Scholar
3)Hutt, S., PhD-Thesis, MPI für Metallforschung, Germany (2001)Google Scholar
4)Möobus, G. et al., J. Microscopy 190(1/2) (1998) 109130CrossRefGoogle Scholar
5)Browning, N.D., Pennycook;, S.J.J. Phys. D29 (1996)1779Google Scholar
6)The use of the facilities of the Max-Planck-lnstitut fur Metallforschung, Germany is gratefully acknowledgedGoogle Scholar