Ulteriori informazioni
This book has three keywords: X-ray resonant scattering, diffraction, and multiple scattering. X-ray resonant scattering occurs due to the excitation of the inner shell electrons of atoms. Now that it is possible to obtain high-intensity X-rays with a continuous spectrum using synchrotron radiation, the use of resonant scattering becomes easier. Recent advances in crystal growth technology enables us to create many perfect crystals. X-ray multiple scattering is important in perfect crystals, and dynamical theory of X-ray diffraction deals with it.
In addition to ordinary scattering processes due to Thomson scattering, this book explains resonant scattering in detail, discusses the phase problems using resonant scattering, and derives a dynamic diffraction theory that treats it equivalently to Thomson scattering. The characteristics of dynamical diffraction due to resonant scattering and its experimental verification are explained. The effect of anomalous transmission in resonant dynamical diffraction, which greatly reduces the absorption coefficient, are discussed along with its important applications. For example, under anomalous transmission conditions, the trajectory of an X-ray in a slightly curved parallel plate crystal becomes parabolic. By confining this X-ray within a thin crystal, a waveguide can be formed that allows the X-ray to propagate long distances within the crystal.
Sommario
Introduction.- X-ray diffraction from microcrystal.- X-ray resonant scattering.- Optical properties of X-rays.- Basic equations of X-ray dynamical diffraction.- Dynamical theory of diffraction for non-absorbing crystal.- Resonant scattering and dynamical theory of diffraction.- Dynamical diffraction of X-ray wave-packet with finite spectral width.- Dynamical diffraction for slightly strained crystals.- Appendices.- Index.
Info autore
Tomoe Fukamachi is a professor emeritus at the Saitama Institute of Technology in Japan and a visiting professor at Anhui University in China. He has been awarded for his work by the Crystallographic Society of Japan. The specific area of his work mainly covers theory and experiments on resonant scattering dynamical diffraction, and the analysis of different types of interference fringes (e.g., X-ray mirage fringes) produced by X-ray beams propagating through slightly curved thin crystals (X-ray waveguides).
Takaaki Kawamurais a professor emeritus at the University of Yamanashi and a researcher at the Institute of Industrial Science, the University of Tokyo, and Tokyo Denki University. The specific area of his work mainly covers dynamical theory or multiple scattering theory of X-ray diffraction as well as electron diffraction; the phase problem in the field of diffraction including using oversampling approach; simulation studies of molecular beam epitaxy; and crystal growth.
Riassunto
This book has three keywords: X-ray resonant scattering, diffraction, and multiple scattering. X-ray resonant scattering occurs due to the excitation of the inner shell electrons of atoms. Now that it is possible to obtain high-intensity X-rays with a continuous spectrum using synchrotron radiation, the use of resonant scattering becomes easier. Recent advances in crystal growth technology enables us to create many perfect crystals. X-ray multiple scattering is important in perfect crystals, and dynamical theory of X-ray diffraction deals with it.
In addition to ordinary scattering processes due to Thomson scattering, this book explains resonant scattering in detail, discusses the phase problems using resonant scattering, and derives a dynamic diffraction theory that treats it equivalently to Thomson scattering. The characteristics of dynamical diffraction due to resonant scattering and its experimental verification are explained. The effect of anomalous transmission in resonant dynamical diffraction, which greatly reduces the absorption coefficient, are discussed along with its important applications. For example, under anomalous transmission conditions, the trajectory of an X-ray in a slightly curved parallel plate crystal becomes parabolic. By confining this X-ray within a thin crystal, a waveguide can be formed that allows the X-ray to propagate long distances within the crystal.
