Advances in Imaging and Electron Physics Advances in Imaging and Electron Physics Series
Coordonnateurs : Hawkes Peter W., Hÿtch Martin
Preface
1. Novel theory of the structure of elementary particles
H. Rose
2. Electron diffractive optics based on the magnetic Aharonov-Bohm effect
Román Castañeda, Pablo Bedoya-Ríos and Giorgio Matteucci
3. Electronic image recording in conventional electron microscopy
K.-H. Herrmann and D. Krahl
4. The phase problem in electron microscopy
D. L. Misell
Dr Martin Hÿtch, serial editor for the book series “Advances in Imaging and Electron Physics (AIEP), is a senior scientist at the French National Centre for Research (CNRS) in Toulouse. He moved to France after receiving his PhD from the University of Cambridge in 1991 on “Quantitative high-resolution transmission electron microscopy (HRTEM), joining the CNRS in Paris as permanent staff member in 1995. His research focuses on the development of quantitative electron microscopy techniques for materials science applications. He is notably the inventor of Geometric Phase Analysis (GPA) and Dark-Field Electron Holography (DFEH), two techniques for the measurement of strain at the nanoscale. Since moving to the CEMES-CNRS in Toulouse in 2004, he has been working on aberration-corrected HRTEM and electron holography for the study of electronic devices, nanocrystals and ferroelectrics. He was laureate of the prestigious European Microscopy Award for Physical Sciences of the European Microscopy Society in 2008. To date he has published 130 papers in international journals, filed 6 patents and has given over 70 invited talks at international conferences and workshops.
- Provides the authority and expertise of leading contributors from an international board of authors
- Presents the latest release in the Advances in Imaging and Electron Physics
Date de parution : 03-2023
Ouvrage de 284 p.
15x22.8 cm
Thèmes d’Advances in Imaging and Electron Physics :
Mots-clés :
4D angular momentum; Aharonov–Bohm Effect; Analysis; Camera tubes; Channel plates; Detection quantum efficiency; Four-dimensional (4D) Hamiltonian; Geometric potential; Holography; Image intensifier design; Image processing; Lamb shift; Massless quarks; Minkowski space; Origin of mass and charge; Phase diffraction; Reconstruction; Scintillator properties; Signal amplification; Single electron interference; Single particle confinement; Solid-state converters; Space-time rotations; Spatial modulators; Spatially structured Lorentzian wells; Storage systems; Universal time