Electron holography : proceedings of the International Workshop on Electron Holography, Holiday Inn World's Fair, Knoxville, Tennessee, USA, August 29-31, 1994

Electron holography is a very powerful technique which uses the phase information in the electron image to study fundamental physics of matter at the micrometer to nanometer scale, or even to Angstrom scale. A few years ago, successful examples of electron holography included confirmation of Aharonov-Bohm (AB) effect and direct visualization of magnetic fields not only outside but also inside of magnetic materials. Since then, fields of application of electron holography have expanded from solid state physics to materials science and the biological sciences, and new techniques have been invented including real-time holography and computed tomography of the reconstructed phase image. Containing contributions from electron holography experts, this book provides a review of recent developments and future prospects, presented by the innovators in this field. The chapters cover a wide area of application fields and new techniques; magnetic fluxes (vortices) in superconductors, magnetic domains, magnetic and electric microfields, and p-n junctions, catalysts, biological filaments, fine particles, and fullerenes for materials applications. Chapters are also included on digital recording and processing, real-time electron holography, computed tomography and STEM holography.

• Part 1 Introduction to electron holography: progress in holographic interference electron microscopy, A. Tonomura
• electron holography - state and experimental steps towards 0.1 nm with the CM30-special tubingen, H. Lichte. Part 2 Holographic interference electron microscopy - techniques: digital recording and processing of electron off-axis holography, G. Ade
• observation of atomic surface potential by electron holography, T. Tanji and K. Ishizuka
• phase-shifting techniques in electron holography, Q. Ru
• holographic reconstruction methods, M. Lehmann and H. Lichte
• real-time electron holography using a liquid-crystal panel, J. Chen et al
• electron holographic computed tomography, G. Lai et al
• practical electron holography - applications of advanced hologram processing techniques to materials science problems, E. Volkl et al
• retrieval of atomic displacements from reconstructed electron waves as an ill-posed inverse problem, K. Scheerschmidt and F. Knoll. Part 3 Holographic interference electron microscopy - applications: interference- and lorentz-image simulations of vortices in superconductors, G. Pozzi et al
• magnetic field observation of vortices in superconductors by electron holography, J.E. Bonevich et al
• holographic studies on magnetic phenomena in small regions, T. Hirayama et al
• electron holography of magnetic and electric microfields, G. Matteucci et al
• holography of electrostatic fields, B.G. Frost et al
• quantitative applications of off-axis electron holography, D.J. Smith et al
• electron holography of p-n junctions, M.R. McCartney et al
• electron holography of heterogeneous catalysts, A.K. Datye et al
• electron holography in materials science, X. Lin et al
• electron holography applied to the study of fullerene materials, L.F. Allard et al
• transmission electron holography of polymer microstructure, M. Libera et al
• electron holographic observation of thin biological filaments, K. Aoyama et al
• Fraunhofer in-line electron holography of small weak-phase objects, T. Matsumoto et al. Part 4 New types of electron holography: state of the art of low-energy electron holography, H.-W. Fink et al
• on the reconstruction of low voltage point projection holograms, J.C.H. Spence et al
• coherent electron diffraction and holography, J.W. Steeds et al
• modelling of convergent beam interferometry, R.A. Herring and G. Pozzi
• interpreting the reconstructed object waves, D. Van Dyck and M. Op de Beeck
• focal series wave function reconstruction in HRTEM, M. Op de Beeck et al
• high-resolution tilted single-sideband holography, K. Ishizuka
• STEM holography of magnetic materials, M. Mankos et al
• amplitude-division electron holography, Q. Ru.