X-Ray Science and Technology,Alan G. Michette, Christopher J. Buckley A much-needed course text in the science and applications of x-rays. Its clear, practical approach also makes it an accessible introduction to x-rays for researchers moving into, for example, x-ray lithography, plasma diagnostics, or x-ray astronomy. The sources of x-rays and how they compare, x-ray manipulation and detection, the uses of x-rays, and even the manufacture of x-ray optical devices are all described and explained, giving the reader a sound grounding in fundamental x-ray optics and techniques. Many references and suggestions for further reading make it easy to progress further in your understanding of the subject. |
Contents
ElectronImpact XRay Sources | 48 |
3 | 57 |
Synchrotron Radiation Sources | 64 |
Copyright | |
8 other sections not shown
Common terms and phrases
aberration absorption edges acceleration amplitude angle angular anode astigmatism beam betatron Bragg Bragg-Fresnel bremsstrahlung cathode channel Channel Electron Multipliers charge coefficient components constant crystal described detector diffraction grating distance distribution electron density emission emitted equation etching EXAFS field film flux focal focusing frequency Fresnel equations Fresnel zone plate function given gives grazing incidence grooves ideal orbit intensity ionisation lattice layer length linear material measured Michette A G micrometres multilayer mirrors obtained oscillations particles pattern phase photocathode photon Phys plane plasma polarised produce pulse quantum radius range reflection gratings refractive index resist shown in figure spatial resolution spectral spectrum spherical Springer storage rings structure substrate surface synchrotron radiation target thickness Thomson scattering transitions typically values voltage wave wavelength width x-ray energy x-ray lasers X-Ray Microscopy x-ray optics x-ray sources zero zone plate