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

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xii Preface textbooks, such as Williams and Carter (1996) and the excellent Springer books by Reimer. Even so, I hope that some of my research colleagues may find the current book to be a useful supplement to their collection. My aim has been to teach general concepts, such as how a magnetic lens focuses electrons, without getting into too much detail � as would be needed to actually design a magnetic lens. Because electron microscopy is interdisciplinary, both in technique and application, the physical principles being discussed involve not only physics but also aspects of chemistry, electronics, and spectroscopy. I have included a short final chapter outlining some recent or more advanced techniques, to illustrate the fact that electron microscopy is a “living” subject that is still undergoing development. Although the text contains equations, the mathematics is restricted to simple algebra, trigonometry, and calculus. SI units are utilized throughout. I have used italics for emphasis and bold characters to mark technical terms when they first appear. On a philosophical note: although wave mechanics has proved invaluable for accurately calculating the properties of electrons, classical physics provides a more intuitive description at an elementary level. Except with regard to diffraction effects, I have assumed the electron to be a particle, even when treating “phase contrast” images. I hope Einstein would approve. To reduce publishing costs, the manuscript was prepared as camera-ready copy. I am indebted to several colleagues for proofreading and suggesting changes to the text; in particular, Drs. Marek Malac, Al Meldrum, Robert Wolkow, and Rodney Herring, and graduate students Julie Qian, Peng Li, and Feng Wang. January 2005 Ray Egerton University of Alberta Edmonton, Canada regerton@ualberta.ca
Chapter 1 AN INTRODUCTION TO MICROSCOPY Microscopy involves the study of objects that are too small to be examined by the unaided eye. In the SI (metric) system of units, the sizes of these objects are expressed in terms of sub-multiples of the meter, such as the micrometer (1 �m = 10 -6 m, also called a micron) and also the nanometer (1 nm = 10 -9 m). Older books use the Angstrom unit (1 Å = 10 -10 m), not an official SI unit but convenient for specifying the distance between atoms in a solid, which is generally in the range 2 � 3 Å. To describe the wavelength of fast-moving electrons or their behavior inside an atom, we need even smaller units. Later in this book, we will make se of the picometer (1 pm = 10 -12 u m). The diameters of several small objects of scientific or general interest are listed in Table 1-1, together with their approximate dimensions. Table 1-1. Approximate sizes of some common objects and the smallest magnification M* required to distinguish them, according to Eq. (1.5). Object Typical diameter D M* = 75�m / D Grain of sand 1 mm = 1000 µm None Human hair 150 µm None Red blood cell 10 µm 7.5 Bacterium 1 µm 75 Virus 20 nm 4000 DNA molecule 2 nm 40,000 Uranium atom 0.2 nm = 200 pm 400,000
Page 2 and 3: Physical Principles of Electron Mic
Page 4 and 5: Ray F. Egerton Department of Physic
Page 6 and 7: Contents Preface xi 1. An Introduct
Page 8 and 9: Contents ix 7. Recent Developments
Page 12 and 13: 2 1.1 Limitations of the Human Eye
Page 14 and 15: 4 Chapter 1 parallel beam of light
Page 16 and 17: 6 Chapter 1 Figure 1-3. One of the
Page 18 and 19: 8 Chapter 1 Figure 1-5. Light-micro
Page 20 and 21: 10 Chapter 1 Figure 1-7. Scanning t
Page 22 and 23: 12 Chapter 1 Figure 1-8. Early phot
Page 24 and 25: 14 Chapter 1 Figure 1-10. JEOL tran
Page 26 and 27: 16 Chapter 1 hydrated. But high-ene
Page 28 and 29: 18 Chapter 1 Figure 1-14. Scanning
Page 30 and 31: 20 Chapter 1 Figure 1-16. Photograp
Page 32 and 33: 22 Chapter 1 visible-light photons
Page 34 and 35: 24 Chapter 1 Typically, the STM hea
Page 36 and 37: Chapter 2 ELECTRON OPTICS Chapter 1
Page 38 and 39: Electron Optics 29 a c b object len
Page 40 and 41: Electron Optics 31 � a n 2 ~1.5
Page 42 and 43: Electron Optics 33 We can define im
Page 44 and 45: Electron Optics 35 electron source
Page 46 and 47: Electron Optics 37 symmetry and use
Page 48 and 49: Electron Optics 39 As we said earli
Page 50 and 51: Electron Optics 41 2.4 Focusing Pro
Page 52 and 53: Electron Optics 43 � = [e/(8mE0)
Page 54 and 55: Electron Optics 45 image plane. Whe
Page 56 and 57: Electron Optics 47 procedure that i
Page 58 and 59: 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
Page 104 and 105:
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
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118 Chapter 4 High-magnification ph
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120 Chapter 4 At this stage it is c
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122 Chapter 4 All of the above meth
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124 Chapter 4 The procedures outlin
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126 Chapter 5 specimen scan coils o
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128 Chapter 5 functions with m and
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130 Chapter 5 inelastic collisions
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132 Chapter 5 Figure 5-5. Dependenc
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134 Chapter 5 Figure 5-7. (a) Secon
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136 Chapter 5 Because each secondar
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138 Chapter 5 Backscattered electro
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140 Chapter 5 Whereas Ip remains co
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142 Chapter 5 Figure 5-14. Red, gre
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144 Chapter 5 the SE2 and SE3 compo
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146 Chapter 5 just-observable loss
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148 Chapter 5 Section 4-10. Films o
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150 Chapter 5 A backscattered-elect
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152 Chapter 5 One example of this p
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Chapter 6 ANALYTICAL ELECTRON MICRO
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Analytical Electron Microscopy 157
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Page 176 and 177:
Page 178 and 179:
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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
Page 200 and 201:
REFERENCES Binnig, G., Rohrer, H.,
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INDEX Aberrations, 3, 28 axial, 44
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Index 199 EELS, 172 Electromagnetic
Page 206 and 207:
Index 201 Principal plane, 32, 80 P
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