Elements of X-ray DiffractionThis is a reproduction of a book published before 1923. This book may have occasional imperfections such as missing or blurred pages, poor pictures, errant marks, etc. that were either part of the original artifact, or were introduced by the scanning process. We believe this work is culturally important, and despite the imperfections, have elected to bring it back into print as part of our continuing commitment to the preservation of printed works worldwide. We appreciate your understanding of the imperfections in the preservation process, and hope you enjoy this valuable book. |
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Page 355
... atomic number Z. Therefore , if A and B have nearly the same atomic number , the a and ẞ phases will consist of atoms having almost the same scattering powers , and the intensities of the a and ẞ diffraction patterns will also be ...
... atomic number Z. Therefore , if A and B have nearly the same atomic number , the a and ẞ phases will consist of atoms having almost the same scattering powers , and the intensities of the a and ẞ diffraction patterns will also be ...
Page 373
... atoms involved have almost the same atomic numbers , and that is by the proper choice of the incident wavelength . In the discussion of atomic scattering factors given in Sec . 4-3 it was tacitly assumed that the atomic scattering ...
... atoms involved have almost the same atomic numbers , and that is by the proper choice of the incident wavelength . In the discussion of atomic scattering factors given in Sec . 4-3 it was tacitly assumed that the atomic scattering ...
Page 488
... atomic number Z and with scattering angle 20 . The scattering power of an atom increases as Z increases and ... atomic number ; in other words , there is no regular variation between scattering power for neutrons and the atomic number of ...
... atomic number Z and with scattering angle 20 . The scattering power of an atom increases as Z increases and ... atomic number ; in other words , there is no regular variation between scattering power for neutrons and the atomic number of ...
Contents
THE GEOMETRY OF CRYSTALS | 29 |
CHAPTER 3 | 78 |
CHAPTER 4 | 104 |
Copyright | |
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Common terms and phrases
absorption coefficient absorption edge alloy analysis angle atomic number austenite axis back-reflection Bragg angle Bragg law Bravais lattice calculated camera circle composition constant cosē counter crystal cubic curve Debye ring Debye-Scherrer decrease determined diffracted beam diffraction lines diffraction pattern diffractometer direction distance electrons elements equation error example face-centered face-centered cubic factor film filter fluorescent fluorescent radiation given grain hexagonal incident beam indices integrated intensity lattice parameter martensite measured metal normal obtained orientation Orthorhombic parallel percent phase photograph pinhole pole figure position powder pattern produced projection pulses rays reciprocal lattice reciprocal-lattice reflecting planes relative residual stress rhombohedral rotation sample scattering shown in Fig sinē slit solid solution spacing specimen spectrometer sphere spots stereographic structure substance surface temperature tetragonal thickness tion transmission twin unit cell values vector voltage wave wavelength x-ray diffraction x-ray method x-ray tube zero zone