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 3 and 4: Ray F. Egerton Physical Principles
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Page 9: PREFACE The telescope transformed o
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52 Chapter 2 P (a) P (b) y y x x +V
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54 Chapter 2 The stigmators found i
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Chapter 3 THE TRANSMISSION ELECTRON
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The Transmission Electron Microscop
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Chapter 4 TEM SPECIMENS AND IMAGES
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TEM Specimens and Images 95 v 0 m M
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TEM Specimens and Images 97 In prac
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TEM Specimens and Images 99 P e (>
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TEM Specimens and Images 101 4.4 Sc
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TEM Specimens and Images 103 Figure
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TEM Specimens and Images 105 as see
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TEM Specimens and Images 107 dimens
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TEM Specimens and Images 109 (discu
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TEM Specimens and Images 111 Figure
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TEM Specimens and Images 113 core,
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TEM Specimens and Images 115 unders
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TEM Specimens and Images 117 underf
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TEM Specimens and Images 119 From t
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TEM Specimens and Images 121 (a) (b
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TEM Specimens and Images 123 of a s
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Chapter 5 THE SCANNING ELECTRON MIC
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The Scanning Electron Microscope 12
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156 Chapter 6 where h = 6.63 � 10
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158 Chapter 6 Many-electron atoms r
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160 Chapter 6 Figure 6-2 also demon
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162 Chapter 6 x-ray computer & disp
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164 Chapter 6 Ideally, each peak in
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166 Chapter 6 to balance the units
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168 Chapter 6 a three-dimensional d
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170 Chapter 6 to be analyzed, where
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172 Chapter 6 different from the co
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174 Chapter 6 A typical energy-loss
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Chapter 7 RECENT DEVELOPMENTS 7.1 S
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Recent Developments 179 Figure 7-2.
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Recent Developments 181 below 0.1 n
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Recent Developments 183 one type of
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Recent Developments 185 Besides hav
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Recent Developments 187 Figure 7-7.
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Recent Developments 189 holder cont
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192 Appendix cathode vacuum + + + +
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194 Appendix The variable � repre
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196 References Neutze, R., Wouts, R
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198 Index Bright-field image, 100 B
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200 Index Inner-shell ionization, 1
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202 Index Stacking fault, 114 Stage
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