Physical Principles of Electron Microscopy: An Introduction to TEM ...

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Analytical Electron Microscopy 169 electron beam specimen x-rays Rowland circle +3kV detector crystal Figure 6-6. Schematic diagram of an XWDS system. For simplicity, the Bragg-reflecting planes are shown as being parallel to the surface of the analyzing crystal. The crystal and detector move around the Rowland circle (dashed) in order to record the spectrum. mechanical force) into a slightly-curved shape, which also provides a degree of focusing similar to that of a concave mirror; see Fig. 6-6. Although XWDS can be performed by adding the appropriate mechanical and electronic systems to an SEM, there exists a more specialized instrument, the electron-probe microanalyzer (EPMA), which is optimized for such work. It generates an electron probe with substantial current, as required to record an x-ray spectrum with good statistics (low noise) within a reasonable time period. The EPMA is fitted with several analyzer/detector assemblies so that more than a single wavelength range can be recorded simultaneously. 6.7 Comparison of XEDS and XWDS Analysis A big advantage of the XEDS technique is the speed of data acquisition, due largely to the fact that x-rays within a wide energy range are detected and analyzed simultaneously. In contrast, the XWDS system examines only one wavelength at any one time and may take several minutes to scan the required wavelength range. The XEDS detector can be brought very close (within a few mm) of the specimen, allowing about 1% of the emitted x-rays
170 Chapter 6 to be analyzed, whereas the XWDS analyzing crystal needs room to move and subtends a smaller (solid) angle, so that much less than 1% of the x-ray photons are collected. Although a commercial XEDS system costs $50,000 or more, this is considerably less expensive than an EPMA machine or XWDS attachment to an SEM. The main advantage of the XWDS system is that it provides narrow xray peaks (width � 5 eV, rather than > 100 eV for XEDS system) that stand out clearly from the background; see Fig. 6-7. This is particularly important when analyzing low-Z elements (whose K-peaks are more narrowly spaced) or elements present at low concentration, whose XEDS peaks would have a low signal/background ratio, resulting in a poor accuracy of measurement. Consequently, XWDS analysis is the preferred method for measuring low concentrations: 200 parts per million (ppm) is fairly routine and 1 ppm is detectable in special cases. At higher concentrations, the narrow XWDS peak allows a measurement accuracy of better than 1% with the aid of ZAF corrections. In contrast, the accuracy of XEDS analysis is usually not better than 10%. Figure 6-7. X-ray intensity as a function of photon energy (in the range 2.1 to 2.7 keV), recorded from a molybdenum disulfide (MoS2) specimen using (a) XWDS and (b) XEDS. The wavelength-dispersed spectrum displays peaks due to Mo and S, whereas these peaks are not separately resolved in the energy-dispersed spectrum due to the inadequate energy resolution Courtesy of S. Matveev, Electron Microprobe Laboratory, University of Alberta.
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Physical Principles of Electron Mic
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Ray F. Egerton Department of Physic
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Contents Preface xi 1. An Introduct
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Contents ix 7. Recent Developments
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xii Preface textbooks, such as Will
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2 1.1 Limitations of the Human Eye
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4 Chapter 1 parallel beam of light
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6 Chapter 1 Figure 1-3. One of the
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8 Chapter 1 Figure 1-5. Light-micro
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10 Chapter 1 Figure 1-7. Scanning t
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12 Chapter 1 Figure 1-8. Early phot
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14 Chapter 1 Figure 1-10. JEOL tran
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16 Chapter 1 hydrated. But high-ene
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18 Chapter 1 Figure 1-14. Scanning
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20 Chapter 1 Figure 1-16. Photograp
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22 Chapter 1 visible-light photons
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24 Chapter 1 Typically, the STM hea
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Chapter 2 ELECTRON OPTICS Chapter 1
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Electron Optics 29 a c b object len
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Electron Optics 31 � a n 2 ~1.5
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Electron Optics 33 We can define im
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Electron Optics 35 electron source
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Electron Optics 37 symmetry and use
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Electron Optics 39 As we said earli
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Electron Optics 41 2.4 Focusing Pro
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Electron Optics 43 � = [e/(8mE0)
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Electron Optics 45 image plane. Whe
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Electron Optics 47 procedure that i
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Electron Optics 49 The basic physic
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Electron Optics 51 From Eq. (2.7),
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Electron Optics 53 y +V 1 +V 2 -V 2
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Electron Optics 55 point from the o
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58 Chapter 3 3.1 The Electron Gun T
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60 Chapter 3 The rate of electron e
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62 Chapter 3 electron emission curr
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64 Chapter 3 As seen from the right
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66 Chapter 3 � r r s r � (a) (b
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68 Chapter 3 Table 3-2. Speed v and
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70 Chapter 3 where G is a large amp
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72 Chapter 3 The second condenser (
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74 Chapter 3 Figure 3-9 summarizes
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76 Chapter 3 resolution (especially
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78 Chapter 3 The major advantage of
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80 Chapter 3 contrast (for a given
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82 Chapter 3 A more correct procedu
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84 Chapter 3 diffraction pattern (s
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86 Chapter 3 Nowadays, photographic
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88 Chapter 3 A related concept is d
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90 Chapter 3 molecules, imparting a
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92 Chapter 3 Frequently, liquid nit
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94 Chapter 4 -e -e -e -e +Ze Figure
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96 Chapter 4 � (a) elastic z x m
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98 Chapter 4 � b a (a) (b) Figure
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100 Chapter 4 fraction of electrons
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102 Chapter 4 whose composition or
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104 Chapter 4 replica crystallites
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106 Chapter 4 4.5 Diffraction Contr
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108 Chapter 4 remain undiffracted (
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110 Chapter 4 Close examination of
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112 Chapter 4 Unfortunately, the va
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114 Chapter 4 Crystals can also con
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116 Chapter 4 A simple example of p
Page 126 and 127: 118 Chapter 4 High-magnification ph
Page 128 and 129: 120 Chapter 4 At this stage it is c
Page 130 and 131: 122 Chapter 4 All of the above meth
Page 132 and 133: 124 Chapter 4 The procedures outlin
Page 134 and 135: 126 Chapter 5 specimen scan coils o
Page 136 and 137: 128 Chapter 5 functions with m and
Page 138 and 139: 130 Chapter 5 inelastic collisions
Page 140 and 141: 132 Chapter 5 Figure 5-5. Dependenc
Page 142 and 143: 134 Chapter 5 Figure 5-7. (a) Secon
Page 144 and 145: 136 Chapter 5 Because each secondar
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Page 148 and 149: 140 Chapter 5 Whereas Ip remains co
Page 150 and 151: 142 Chapter 5 Figure 5-14. Red, gre
Page 152 and 153: 144 Chapter 5 the SE2 and SE3 compo
Page 154 and 155: 146 Chapter 5 just-observable loss
Page 156 and 157: 148 Chapter 5 Section 4-10. Films o
Page 158 and 159: 150 Chapter 5 A backscattered-elect
Page 160 and 161: 152 Chapter 5 One example of this p
Page 162 and 163: Chapter 6 ANALYTICAL ELECTRON MICRO
Page 164 and 165: Analytical Electron Microscopy 157
Page 184 and 185: 178 Chapter 7 Figure 7-1. Modified
Page 186 and 187: 180 Chapter 7 7.2 Aberration Correc
Page 188 and 189: 182 Chapter 7 Besides decreasing th
Page 190 and 191: 184 Chapter 7 7.4 Electron Holograp
Page 192 and 193: 186 Chapter 7 There are now many al
Page 194 and 195: 188 Chapter 7 holography could ther
Page 196 and 197: Appendix MATHEMATICAL DERIVATIONS A
Page 198 and 199: Mathematical Derivations 193 A.2 Im
Page 200 and 201: REFERENCES Binnig, G., Rohrer, H.,
Page 202 and 203: INDEX Aberrations, 3, 28 axial, 44
Page 204 and 205: Index 199 EELS, 172 Electromagnetic
Page 206 and 207: Index 201 Principal plane, 32, 80 P
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