X-Rays and Extreme Ultraviolet Radiation: Principles and ApplicationsWith this fully updated second edition, readers will gain a detailed understanding of the physics and applications of modern X-ray and EUV radiation sources. Taking into account the most recent improvements in capabilities, coverage is expanded to include new chapters on free electron lasers (FELs), laser high harmonic generation (HHG), X-ray and EUV optics, and nanoscale imaging; a completely revised chapter on spatial and temporal coherence; and extensive discussion of the generation and applications of femtosecond and attosecond techniques. Readers will be guided step by step through the mathematics of each topic, with over 300 figures, 50 reference tables and 600 equations enabling easy understanding of key concepts. Homework problems, a solutions manual for instructors, and links to YouTube lectures accompany the book online. This is the 'go-to' guide for graduate students, researchers and industry practitioners interested in X-ray and EUV interaction with matter. |
Contents
| 1 | |
Radiation and Scattering at EUV and XRay Wavelengths | 27 |
Wave Propagation and Refractive Index at XRay and EUV Wavelengths | 60 |
Coherence at Short Wavelengths | 110 |
Synchrotron Radiation | 148 |
Laser High Harmonic Generation | 279 |
Physics of Hot Dense Plasmas | 315 |
Extreme Ultraviolet and Soft XRay Lasers | 403 |
Units and Physical Constants | 567 |
Atomic Scattering Factors Atomic Absorption Coefficients | 578 |
Mathematical and Vector Relationships | 592 |
Some Integrations in k ωSpace | 602 |
Frequency and Wavenumber Relations | 608 |
The Lorentz Contraction of Length | 612 |
Other editions - View all
X-Rays and Extreme Ultraviolet Radiation: Principles and Applications David Attwood,Anne Sakdinawat No preview available - 2020 |
Common terms and phrases
absorption amplitude angle angular aperture atomic attosecond axial bending magnet Chapter coherence length crystal diffraction duration electric field electromagnetic electron beam electron density Electron Laser emission equation factor femtosecond filtering finite focal focusing free electron Free-Electron Laser frequency function FWHM hard x-ray high harmonic illumination illustrated in Figure incident intensity interface ionization ions laser pulse lasing length lens Lett magnetic field microscope mirror multilayer Nature Photon nm wavelength numerical aperture observed obtained Optics oscillation parameter pattern peak phase space phase velocity photon energy photon flux Phys pinhole plane plasma polarization power radiated propagation radiated power reflection refractive index region sample scattering Section shown in Figure soft x-ray spatial coherence synchrotron radiation technique temperature tion total external reflection transverse undulator radiation vector wave wavelength wiggler X-Ray Laser X-ray Microscopy zone plate