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 210
... scales available to cover var- ious ranges of x - ray intensity ( 100 , 1000 , and 10,000 cps for full - scale deflection of the recorder pen , for example ) . Smaller time constants are used with the higher scales , just as short ...
... scales available to cover var- ious ranges of x - ray intensity ( 100 , 1000 , and 10,000 cps for full - scale deflection of the recorder pen , for example ) . Smaller time constants are used with the higher scales , just as short ...
Page 305
... scale is then constructed ; it extends over two ranges of the [ ( h2 + k2 ) + 12 / ( c / a ) 2 ] scale and runs in the opposite direction , since the coefficient of log d in Eq . ( 10-4 ) is 2 times the coefficient of log [ ( h2 + k2 ) ...
... scale is then constructed ; it extends over two ranges of the [ ( h2 + k2 ) + 12 / ( c / a ) 2 ] scale and runs in the opposite direction , since the coefficient of log d in Eq . ( 10-4 ) is 2 times the coefficient of log [ ( h2 + k2 ) ...
Page 307
... scale in Fig . 10–4 , which applies to body - centered tetragonal lattices . Note that the curves of high indices are often so crowded that it is difficult to assign the proper indices to the observed lines . It then becomes necessary ...
... scale in Fig . 10–4 , which applies to body - centered tetragonal lattices . Note that the curves of high indices are often so crowded that it is difficult to assign the proper indices to the observed lines . It then becomes necessary ...
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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 chart circle composition constant copper atoms cos² counter cubic curve Debye ring Debye-Scherrer decreases determined diffracted beam diffraction lines diffraction pattern diffractometer direction distance electrons elements equation error example face-centered face-centered cubic factor film fluorescent fluorescent radiation given grain hexagonal incident beam indices integrated intensity lattice parameter Laue method martensite measured metal normal obtained Orthorhombic parallel percent phase photograph pinhole plotted pole figure position powder pattern preferred orientation projection reciprocal lattice reciprocal-lattice reflecting planes relative residual stress rhombohedral rotation sample scattering shown in Fig sin² slit solid solution spacing specimen spectrometer sphere spot stereographic substance surface temperature tetragonal thickness tion transmission unit cell values vector voltage wavelength x-ray diffraction x-ray method x-ray tube zero zone