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

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108 Chapter 4 remain undiffracted (undeviated) and will pass through the objective aperture. The grain structure of a polycrystalline material can therefore be seen in a TEM image as an intensity variation between different regions; see Fig. 4-12a or Fig. 4-21. A TEM image is said to display diffraction contrast in any situation in which the intensity variations arise from differences in diffracting conditions between different regions of the specimen. 4.6 Dark-Field Images Instead of selecting the undiffracted beam of electrons to form the image, we could horizontally displace the objective aperture so that it admits diffracted electrons. Strongly diffracting regions of specimen would then appear bright relative to their surroundings, resulting in a dark-field image because any part of the field of view that contains no specimen would be dark. Figure 4-12b is an example of dark-field image and illustrates the fact that the contrast is inverted relative to a bright-field image of the same region of specimen. In fact, if it were possible to collect all of the scattered electrons to form the dark-field image, the two images would be complementary: the sum of their intensities would be constant (equivalent to zero contrast). Unless stated otherwise, TEM micrographs are usually bright-field images created with an objective aperture centered about the optic axis. However, one advantage of a dark-field image is that, if the displacement of the objective aperture has been calibrated, the atomic-plane spacing (d) of a bright image feature is known. This information can sometimes be used to identify crystalline precipitates in an alloy, for example. With the procedure just described, the image has inferior resolution compared to a bright-field image because electrons forming the image pass though the imaging lenses at larger angles relative to the optic axis, giving rise to increased spherical and chromatic aberration. However, such loss of resolution can be avoided by keeping the objective aperture on-axis and reorienting the electron beam arriving at the specimen, using the illuminationtilt deflection coils that are built into the illumination system of a materialsscience TEM. 4.7 Electron-Diffraction Patterns Diffraction is the elastic scattering of electrons (deflection by the Coulomb field of atomic nuclei) in a crystalline material. The regularity of the spacing of the atomic nuclei results in a redistribution of the angular dependence of scattering probability, in comparison with that obtained from a single atom
TEM Specimens and Images 109 (discussed in Section 4.3). Instead of a continuous angular distribution, as depicted in Fig. 4-5, the scattering is concentrate`d into sharp peaks (known as Bragg peaks; see Fig. 4-12d) that occur at scattering angles that are twice the Bragg angle �B for atomic planes of a particular orientation. Figure 4-12. (a) Bright-field TEM image of a polycrystalline thin film of bismuth, including bend contours that appear dark. (b) Dark-field image of the same area; bend contours appear bright. (c) Ring diffraction pattern obtained from many crystallites; for recording purposes, the central (0,0,0) diffraction spot has been masked by a wire. (d) Spot diffraction pattern recorded from a single Bi crystallite, whose trigonal crystal axis was parallel to the incident beam. Courtesy of Marek Malac, National Institute of Nanotechnology, Canada. This angular distribution of scattering can be displayed on the TEM screen by weakening the intermediate lens, so that the intermediate and projector lenses magnify the small diffraction pattern initially formed at the back-focal plane of the objective lens. Figure 4-12c is typical of the pattern obtained from a polycrystalline material. It consists of concentric rings, centered on a bright central spot that represents the undiffracted electrons. Each ring corresponds to atomic planes of different orientation and different interplanar spacing d, as indicated in Fig. 4-11b.
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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
Page 66 and 67: 58 Chapter 3 3.1 The Electron Gun T
Page 68 and 69: 60 Chapter 3 The rate of electron e
Page 70 and 71: 62 Chapter 3 electron emission curr
Page 72 and 73: 64 Chapter 3 As seen from the right
Page 74 and 75: 66 Chapter 3 � r r s r � (a) (b
Page 76 and 77: 68 Chapter 3 Table 3-2. Speed v and
Page 78 and 79: 70 Chapter 3 where G is a large amp
Page 80 and 81: 72 Chapter 3 The second condenser (
Page 82 and 83: 74 Chapter 3 Figure 3-9 summarizes
Page 84 and 85: 76 Chapter 3 resolution (especially
Page 86 and 87: 78 Chapter 3 The major advantage of
Page 88 and 89: 80 Chapter 3 contrast (for a given
Page 90 and 91: 82 Chapter 3 A more correct procedu
Page 92 and 93: 84 Chapter 3 diffraction pattern (s
Page 94 and 95: 86 Chapter 3 Nowadays, photographic
Page 96 and 97: 88 Chapter 3 A related concept is d
Page 98 and 99: 90 Chapter 3 molecules, imparting a
Page 100 and 101: 92 Chapter 3 Frequently, liquid nit
Page 102 and 103: 94 Chapter 4 -e -e -e -e +Ze Figure
Page 104 and 105: 96 Chapter 4 � (a) elastic z x m
Page 106 and 107: 98 Chapter 4 � b a (a) (b) Figure
Page 108 and 109: 100 Chapter 4 fraction of electrons
Page 110 and 111: 102 Chapter 4 whose composition or
Page 112 and 113: 104 Chapter 4 replica crystallites
Page 114 and 115: 106 Chapter 4 4.5 Diffraction Contr
Page 118 and 119: 110 Chapter 4 Close examination of
Page 120 and 121: 112 Chapter 4 Unfortunately, the va
Page 122 and 123: 114 Chapter 4 Crystals can also con
Page 124 and 125: 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
Page 146 and 147: 138 Chapter 5 Backscattered electro
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
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Analytical Electron Microscopy 159
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178 Chapter 7 Figure 7-1. Modified
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180 Chapter 7 7.2 Aberration Correc
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182 Chapter 7 Besides decreasing th
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184 Chapter 7 7.4 Electron Holograp
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186 Chapter 7 There are now many al
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188 Chapter 7 holography could ther
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Appendix MATHEMATICAL DERIVATIONS A
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Mathematical Derivations 193 A.2 Im
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REFERENCES Binnig, G., Rohrer, H.,
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INDEX Aberrations, 3, 28 axial, 44
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Index 199 EELS, 172 Electromagnetic
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Index 201 Principal plane, 32, 80 P
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