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Page 67
Figure 2–31(a) is a projection of the two poles P1 and P2 shown in perspective in
Fig. 2–26, and the angle between them is found by the rotation illustrated in Fig. 2
–31(b). This rotation of the projection is equivalent to rotation of the poles on ...
Figure 2–31(a) is a projection of the two poles P1 and P2 shown in perspective in
Fig. 2–26, and the angle between them is found by the rotation illustrated in Fig. 2
–31(b). This rotation of the projection is equivalent to rotation of the poles on ...
Page 224
These angles are then used to determine the three arcs shown in Fig. 8–8. These
are circle arcs, 111 but they are not centered on the cor- %) responding poles;
rather, each one is the locus of points located at an equal angular distance from ...
These angles are then used to determine the three arcs shown in Fig. 8–8. These
are circle arcs, 111 but they are not centered on the cor- %) responding poles;
rather, each one is the locus of points located at an equal angular distance from ...
Page 235
Now the transmission pattern shown in Fig. 8–19 and the back-reflection pattern
shown in Fig. 8–5 were both obtained from the same crystal in the same
orientation relative to the incident beam. The corresponding projections, Figs. 8–
20 and ...
Now the transmission pattern shown in Fig. 8–19 and the back-reflection pattern
shown in Fig. 8–5 were both obtained from the same crystal in the same
orientation relative to the incident beam. The corresponding projections, Figs. 8–
20 and ...
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User Review - ron_benson - LibraryThingExcellent reference book. Needs some updating in terms of advances in detector technology. Read full review
Contents
PROPERTIES OF XRAYS | 1 |
THE GEOMETRY OF CRYSTALS | 29 |
THE DIRECTIONS OF DIFFRACTED BEAMS | 78 |
Copyright | |
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Elements of X-ray Diffraction Bernard Dennis Cullity,Stuart R. Stock,Stuart R.. Stock Snippet view - 2001 |
Common terms and phrases
absorption alloy analysis angle applied atoms axis Bragg calculated camera cause circle composition consider constant contains copper counter counting crystal cubic curve decreases depends described determined diffracted beam diffraction lines diffractometer direction distance effect electrons elements energy equal equation error example factor Figure film fluorescent given gives grain hexagonal incident beam increases indices intensity involved kind known lattice Laue length located material means measured metal method normal observed obtained occur orientation parallel parameter particular pattern percent phase photograph plane plotted pole position possible powder produced projection proportional pulses radiation rays reference reflection relation relative result rotation sample scattering shown shown in Fig shows simple single slit solid solution spacing specimen stress structure substance surface temperature thickness tion tube twin unit cell usually vector voltage wave wavelength x-ray