Elements of X-ray Diffraction |
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Page 69
... shown in Fig . 2-34 by 60 ° about the NS axis , the direction of mo- axia tion being from W to E on the projection . Then A1 moves to A2 along its latitude circle as shown . B1 , however , can rotate only 40 ° before finding itself at ...
... shown in Fig . 2-34 by 60 ° about the NS axis , the direction of mo- axia tion being from W to E on the projection . Then A1 moves to A2 along its latitude circle as shown . B1 , however , can rotate only 40 ° before finding itself at ...
Page 104
... shown in profile in Fig . 4-2 . For the base - centered lattice shown in ( a ) , suppose that the Bragg law is satisfied for the particular values of λ and employed . This means that the path difference ABC between rays 1 ' and 2 ' is ...
... shown in profile in Fig . 4-2 . For the base - centered lattice shown in ( a ) , suppose that the Bragg law is satisfied for the particular values of λ and employed . This means that the path difference ABC between rays 1 ' and 2 ' is ...
Page 256
... shown , then it is possible by a further rotation about the axis AB to bring the { 111 } poles of the standard , shown by open symbols , to positions lying on trace normals , shown by solid symbols . The solid symbols therefore show an ...
... shown , then it is possible by a further rotation about the axis AB to bring the { 111 } poles of the standard , shown by open symbols , to positions lying on trace normals , shown by solid symbols . The solid symbols therefore show an ...
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Common terms and phrases
a₁ absorption coefficient absorption edge alloy analysis angle atomic number austenite axis back-reflection Bragg angle Bragg law Bravais lattice calculated camera circle composition constant copper atoms cos² counter 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 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 sin² slit solid solution spacing specimen spectrometer sphere spot stereographic 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