Tutorial on Off-Axis Electron Holography

Michael Lehmann; Hannes Lichte

doi:10.1017/S1431927602020147

Abstract

Through recent years, off-axis electron holography has helped us to understand and to overcome some experimental restrictions in transmission electron microscopy. With development of powerful electron microscopes, slow-scan CCD cameras, and computers, holography is not an academic technique anymore used by specialized laboratories. Holography has proven its wide range of applications in solving real-world problems in materials science and biology. At medium resolution, that is, on nanometer scale, holography allows access to large area phase contrast produced by magnetic fields and electric potentials. In the high-resolution domain, holography unveils its power by unscrambling amplitude and phase of the electron wave, resulting in an improved lateral resolution up to the information limit. Holography is a thoroughly quantitative method, and, in combination with the perfect zero-loss filtering inherent to this method, the interpretation of the reconstructed data is strongly simplified. After outlining the basics of holography, in this tutorial we focus on development of a step-by-step procedure for recording and reconstruction of holograms. At the end, some recent applications are discussed.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Simon, P. Lichte, H. Drechsel, J. Formanek, P. Graff, A. Wahl, R. Mertig, M. Adhikari, R. and Michler, G.H. 2003. Electron Holography of Organic and Biological Materials. Advanced Materials, Vol. 15, Issue. 17, p. 1475.

Girkin, J M 2003. Optical physics enables advances in multiphoton imaging. Journal of Physics D: Applied Physics, Vol. 36, Issue. 14, p. R250.

Wang, Y.Y. Kawasaki, M. Bruley, J. Gribelyuk, M. Domenicucci, A. and Gaudiello, J. 2004. Off-axis electron holography with a dual-lens imaging system and its usefulness in 2-D potential mapping of semiconductor devices. Ultramicroscopy, Vol. 101, Issue. 2-4, p. 63.

Rau, Wolf-Dieter and Orchowski, Alexander 2004. Mapping of Process-Induced Dopant Redistributions by Electron Holography. Microscopy and Microanalysis, Vol. 10, Issue. 4, p. 462.

Simon, P. Maennig, B. and Lichte, H. 2004. Conventional Electron Microscopy and Electron Holography of Organic Solar Cells. Advanced Functional Materials, Vol. 14, Issue. 7, p. 669.

TWITCHETT, A. C. DUNIN‐BORKOWSKI, R. E. HALLIFAX, R. J. BROOM, R. F. and MIDGLEY, P. A. 2004. Off‐axis electron holography of electrostatic potentials in unbiased and reverse biased focused ion beam milled semiconductor devices. Journal of Microscopy, Vol. 214, Issue. 3, p. 287.

Kirkland, Angus I. and Meyer, Rüdiger R. 2004. “Indirect” High-Resolution Transmission Electron Microscopy: Aberration Measurement and Wavefunction Reconstruction. Microscopy and Microanalysis, Vol. 10, Issue. 4, p. 401.

Simon, P Lichte, H Wahl, R Mertig, M and Pompe, W 2004. Electron holography of non-stained bacterial surface layer proteins. Biochimica et Biophysica Acta (BBA) - Biomembranes, Vol. 1663, Issue. 1-2, p. 178.

Czymmek, Kirk 2005. The Fungal Community. Vol. 20050554, Issue. , p. 307.

Lehmann, Michael 2005. Exit surface dependence of the wavefunction measured and corrected by means of off‐axis electron holography. physica status solidi (a), Vol. 202, Issue. 12, p. 2386.

Simon, Paul Lichte, Hannes Mönter, Damian Reschetilowski, Wladimir Valera, Anibal and Carrillo‐Cabrera, Wilder 2005. Electron Holography, a Versatile Tool for Characterization of Materials: Fluoroapatite‐Gelatine‐Composites, SiC and SiO2. Zeitschrift für anorganische und allgemeine Chemie, Vol. 631, Issue. 6-7, p. 983.

Lenk, Andreas Lichte, Hannes and Muehle, Uwe 2005. 2D-mapping of dopant distribution in deep sub micron CMOS devices by electron holography using adapted FIB-preparation. Microscopy, Vol. 54, Issue. 4, p. 351.

Lehmann, M. and Lichte, H. 2005. Electron holographic material analysis at atomic dimensions. Crystal Research and Technology, Vol. 40, Issue. 1-2, p. 149.

Müller, E. Kruse, P. Gerthsen, D. Schowalter, M. Rosenauer, A. Lamoen, D. Kling, R. and Waag, A. 2005. Measurement of the mean inner potential of ZnO nanorods by transmission electron holography. Applied Physics Letters, Vol. 86, Issue. 15,

Simon, Paul Adhikari, Rameshwar Lichte, Hannes Michler, Goerg H. and Langela, Marc 2005. Electron holography and AFM studies on styrenic block copolymers and a high impact polystyrene. Journal of Applied Polymer Science, Vol. 96, Issue. 5, p. 1573.

Formanek, Peter and Kittler, Martin 2005. Potential and Limitations of Electron Holography in Silicon Research. Solid State Phenomena, Vol. 108-109, Issue. , p. 603.

Fujita, Takeshi Nishimura, Shunichi Fujinami, Takayoshi Kaneko, Kenji Horita, Zenji and Smith, David J. 2006. Application of equal-channel angular pressing to Cu–Co alloy with ferromagnetic precipitates. Materials Science and Engineering: A, Vol. 417, Issue. 1-2, p. 149.

Wang, Liguo Bose, Pulkit S. and Sigworth, Fred J. 2006. Using cryo-EM to measure the dipole potential of a lipid membrane. Proceedings of the National Academy of Sciences, Vol. 103, Issue. 49, p. 18528.

Zweck, Josef and Uhlig, Thomas 2007. Handbook of Magnetism and Advanced Magnetic Materials.

Abrams, Z R Szwarcman, D Lereah, Y Markovich, G and Hanein, Y 2007. Iron assisted growth of copper-tipped multi-walled carbon nanotubes. Nanotechnology, Vol. 18, Issue. 49, p. 495602.

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Tutorial on Off-Axis Electron Holography

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