Advanced Transmission Electron Microscopy

This volume expands and updates the coverage in the authors' popular 1992 book, Electron Microdiffraction . As the title implies, the focus of the book has changed from electron microdiffraction and convergent beam electron diffraction to all forms of advanced transmission electron microscopy. Special attention is given to electron diffraction and imaging, including high-resolution TEM and STEM imaging, and the application of these methods to crystals, their defects, and nanostructures. The authoritative text summarizes and develops most of the useful knowledge which has been gained over the years from the study of the multiple electron scattering problem, the recent development of aberration correctors and their applications to materials structure characterization, as well as the authors' extensive teaching experience in these areas. Advanced Transmission Electron Microscopy: Imaging and Diffraction in Nanoscience is ideal for use as an advanced undergraduate or graduatelevel text in support of course materials in Materials Science, Physics or Chemistry departments.

Serves as an expanded and thoroughly updated successor to the authors' 1992 Electron Microdiffraction, the leading text in the field Improves on previous coverage of electron wave properties and electron diffraction theory in addition to many new chapters in such areas as strain-field analysis and electron detectors Offers comprehensive, quantitative treatments of crystal symmetry, crystal structure and bonding, diffuse scattering, strain measurements, defects and nanostructure characterization Provides new coverage of electron optics, principles of aberration correction and energy filters, electron nanodiffraction techniques, and TEM and STEM imaging theory Presents the latest information on nanostructure analysis, emphasizing quantitative analysis of images and diffraction patterns Includes numerous tables and figures for electron crystallography, and source listings of simulation and modeling computer programs Includes supplementary material: sn.pub/extras

Autorentext
Jian-Min Zuo received his Ph.D. in Physics from Arizona State University in 1989. He is Racheff Professor of Materials Science and Engineering at University of Illinois, Urbana-Champaign. Prior to joining the faculty at the University of Illinois, he was a research scientist in Physics at Arizona State University and a visiting scientist to a number of universities and institutes in Germany, Japan and Norway. His current research topics include nanostructured materials and their structure determination, ferroelectric crystals, diffraction tomography, in-situ and fast electron microscopy. He is the recipient of the 2001 Burton Award of the Microscopy Society of America, Ruska prize of 2015 from German Microscopy Society and fellow of American Physical Society.
John C. H. Spence received his PhD in Physics from Melbourne University in Australia, followed by a postdoc in Materials Science at Oxford, UK. He is Snell Professor of Physics at Arizona State University, where he teaches condensed matter physics. He is a Foreign Member of the Royal Society and Australian Academy, and a Fellow of the American Association for the Advancement of Science. His research interests are in new forms of microscopy, diffraction physics, materials science, condensed matter physics and structural biology. He is currently Director of Science for the NSF Science and Technology Center on the development of X-ray lasers for biology (BIoXFEL).

Klappentext
This volume expands and updates the coverage in the authors' classic 1992 book, "Electron Microdiffraction." As the title implies, the focus of the book has changed from electron microdiffraction, or convergent beam electron diffraction, to electron nanodiffraction and the applications of electron diffraction from single crystals as well as general structure analysis of single crystals, powders, and nanostructures. Advanced Transmission Electron Microscopy provides a comprehensive treatment of theory and practice, and is written at a level suitable for advanced undergraduate students and graduate students and researchers in materials science, chemistry, and physics. Practical guides are provided for interpretation and simulation of electron diffraction patterns.

Inhalt
Introduction and historical background.- Electron Waves and Wave Propagation.- The geometry of electron diffraction patterns.- Kinematical Theory of Electron Diffraction.- Dynamical Theory of Electron Diffraction for Perfect Crystals.- Electron optics.- Lens aberrations and Aberration Correction.- Electron Sources.- Electron Detectors.- Instrumentation and experimental techniques.- Crystal symmetry.- Crystal structure and bonding.- Diffuse Scattering.- Atomic resolution electron imaging.- Imaging and characterization of crystal defects.- Strain Measurements and Mapping.- Structure of Nanocrystals, Nanoparticles and Nanotubes.